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This study provides the first statistically significant evidence that the mechanisms of how pair bonds are created or maintained differ between gibbon taxa. We examine the pair bond in captive pairs of three genera of gibbons (Hylobatidae): siamangs (Symphalangus, N = 17 pairs), crested gibbons (Nomascus, N = 7 pairs), and pileated gibbons (Hylobates pileatus, N = 9 pairs). In the first part of this study, we determine three generally-accepted indicators of pair-bond strength (mutual grooming, behavioral synchronization and partner distance). A pairwise comparison of our samples reveals a difference in relative partner distances between siamangs and pileated gibbons, suggesting that siamangs may have a stronger pair bond than pileated gibbons. No difference among the three taxa was found in other variables believed to indicate pair bond strength. In the second part we examine the amount of partner-directed grooming in each sex. In siamangs, males invest significantly more into pair bonds than females, whereas the opposite is true in crested and pileated gibbons. Our results for siamangs correspond to predictions derived from the 'mate-defense hypothesis' for the evolution of pair bonds, whereas our results for crested gibbons and pileated gibbons correspond to predictions derived from the 'male-services hypothesis'.

Gibbons. --- Hylobatidae --- Hylobatids --- Lesser apes --- Small apes --- Apes --- Primates

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Foamy viruses, currently referred to as spumaretroviruses, are the most ancient retroviruses as evidenced by traces of viral sequences dispersed in all vertebrate classes from fish to mammals. Additionally, infectious foamy viruses circulate in a variety of mammalian species including simian, bovine, equine, caprine, and feline. Foamy viruses have many unique features which led to the division of the retrovirus family into two subfamilies, the Orthoretrovirinae and Spumaretrovirinae. In vitro, foamy viruses have a broad host range and in vivo, human infections have been described due to cross-species transmission from infected nonhuman primates. Thus far, there are no reports of virus-induced disease in humans or in the natural host species. These unique properties of foamy viruses have led researchers to develop foamy viruses as gene therapy vectors to study virus–virus and virus–host interactions for identifying factors involved in virus replication, transmission, and immune regulation that could influence potential clinical outcomes in humans as well as for using endogenous foamy virus sequences in the analysis of host species evolution.

Medicine --- Neurosciences --- spumavirus --- feline illness --- proviral load --- neglected virus --- bovine foamy virus --- infectious clone --- particle release --- cell-free transmission --- foamy virus --- spumaretrovirus --- cross-species virus transmission --- zoonosis --- restriction factors --- immune responses --- FV vectors --- virus replication --- latent infection --- feline foamy virus --- epidemiology --- retrovirus --- Spumaretrovirus --- mountain lion --- Puma concolor --- ELISA --- protease --- reverse transcriptase --- RNase H --- reverse transcription --- antiviral drugs --- resistance --- simian foamy virus --- gibbon --- lesser apes --- co-evolution --- complete viral genome --- equine foamy virus --- isolation --- Japan --- sero-epidemiology --- reptile foamy virus --- endogenous foamy virus --- endogenous retrovirus --- ancient retroviruses --- co-speciation --- foamy virus-host interactions --- viral tropism --- infection --- kidney --- cats --- chronic kidney disease --- chronic renal disease --- integrase --- integration --- co-infections --- NHP --- pathogenesis --- zoonoses --- viral prevalence --- Neotropical primates --- free-living primates --- Brazil --- new world primates --- simian retrovirus --- BFV --- spuma virus --- model system --- animal model --- animal experiment --- miRNA function --- gene expression --- antiviral host restriction --- gene therapy --- in-vivo gene therapy --- hematopoietic stem and progenitor cells --- foamy virus vector --- pre-clinical canine model --- SCID-X1 --- innate sensing --- cGAS --- STING --- foamy viruses --- wild ruminants --- European bison --- red deer --- roe deer --- fallow deer --- seroreactivity --- inter-species transmission --- HSC --- gene marking --- FV gene transfer to HSCs --- gene therapy alternatives --- serotype --- high-throughput sequencing --- replication kinetics --- cytopathic effect --- reverse transcriptase activity --- miRNA expression --- virus-host-interaction --- miRNA target gene identification --- innate immunity --- ANKRD17 --- Bif1 (SH3GLB1) --- replication in vitro --- spumavirus --- feline illness --- proviral load --- neglected virus --- bovine foamy virus --- infectious clone --- particle release --- cell-free transmission --- foamy virus --- spumaretrovirus --- cross-species virus transmission --- zoonosis --- restriction factors --- immune responses --- FV vectors --- virus replication --- latent infection --- feline foamy virus --- epidemiology --- retrovirus --- Spumaretrovirus --- mountain lion --- Puma concolor --- ELISA --- protease --- reverse transcriptase --- RNase H --- reverse transcription --- antiviral drugs --- resistance --- simian foamy virus --- gibbon --- lesser apes --- co-evolution --- complete viral genome --- equine foamy virus --- isolation --- Japan --- sero-epidemiology --- reptile foamy virus --- endogenous foamy virus --- endogenous retrovirus --- ancient retroviruses --- co-speciation --- foamy virus-host interactions --- viral tropism --- infection --- kidney --- cats --- chronic kidney disease --- chronic renal disease --- integrase --- integration --- co-infections --- NHP --- pathogenesis --- zoonoses --- viral prevalence --- Neotropical primates --- free-living primates --- Brazil --- new world primates --- simian retrovirus --- BFV --- spuma virus --- model system --- animal model --- animal experiment --- miRNA function --- gene expression --- antiviral host restriction --- gene therapy --- in-vivo gene therapy --- hematopoietic stem and progenitor cells --- foamy virus vector --- pre-clinical canine model --- SCID-X1 --- innate sensing --- cGAS --- STING --- foamy viruses --- wild ruminants --- European bison --- red deer --- roe deer --- fallow deer --- seroreactivity --- inter-species transmission --- HSC --- gene marking --- FV gene transfer to HSCs --- gene therapy alternatives --- serotype --- high-throughput sequencing --- replication kinetics --- cytopathic effect --- reverse transcriptase activity --- miRNA expression --- virus-host-interaction --- miRNA target gene identification --- innate immunity --- ANKRD17 --- Bif1 (SH3GLB1) --- replication in vitro

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• EndNote
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Foamy viruses, currently referred to as spumaretroviruses, are the most ancient retroviruses as evidenced by traces of viral sequences dispersed in all vertebrate classes from fish to mammals. Additionally, infectious foamy viruses circulate in a variety of mammalian species including simian, bovine, equine, caprine, and feline. Foamy viruses have many unique features which led to the division of the retrovirus family into two subfamilies, the Orthoretrovirinae and Spumaretrovirinae. In vitro, foamy viruses have a broad host range and in vivo, human infections have been described due to cross-species transmission from infected nonhuman primates. Thus far, there are no reports of virus-induced disease in humans or in the natural host species. These unique properties of foamy viruses have led researchers to develop foamy viruses as gene therapy vectors to study virus–virus and virus–host interactions for identifying factors involved in virus replication, transmission, and immune regulation that could influence potential clinical outcomes in humans as well as for using endogenous foamy virus sequences in the analysis of host species evolution.

spumavirus --- feline illness --- proviral load --- neglected virus --- bovine foamy virus --- infectious clone --- particle release --- cell-free transmission --- foamy virus --- spumaretrovirus --- cross-species virus transmission --- zoonosis --- restriction factors --- immune responses --- FV vectors --- virus replication --- latent infection --- feline foamy virus --- epidemiology --- retrovirus --- Spumaretrovirus --- mountain lion --- Puma concolor --- ELISA --- protease --- reverse transcriptase --- RNase H --- reverse transcription --- antiviral drugs --- resistance --- simian foamy virus --- gibbon --- lesser apes --- co-evolution --- complete viral genome --- equine foamy virus --- isolation --- Japan --- sero-epidemiology --- reptile foamy virus --- endogenous foamy virus --- endogenous retrovirus --- ancient retroviruses --- co-speciation --- foamy virus-host interactions --- viral tropism --- infection --- kidney --- cats --- chronic kidney disease --- chronic renal disease --- integrase --- integration --- co-infections --- NHP --- pathogenesis --- zoonoses --- viral prevalence --- Neotropical primates --- free-living primates --- Brazil --- new world primates --- simian retrovirus --- BFV --- spuma virus --- model system --- animal model --- animal experiment --- miRNA function --- gene expression --- antiviral host restriction --- gene therapy --- in-vivo gene therapy --- hematopoietic stem and progenitor cells --- foamy virus vector --- pre-clinical canine model --- SCID-X1 --- innate sensing --- cGAS --- STING --- foamy viruses --- wild ruminants --- European bison --- red deer --- roe deer --- fallow deer --- seroreactivity --- inter-species transmission --- HSC --- gene marking --- FV gene transfer to HSCs --- gene therapy alternatives --- serotype --- high-throughput sequencing --- replication kinetics --- cytopathic effect --- reverse transcriptase activity --- miRNA expression --- virus-host-interaction --- miRNA target gene identification --- innate immunity --- ANKRD17 --- Bif1 (SH3GLB1) --- replication in vitro