sg:pub.10.1007/s00412-015-0565-2 - Springer Nature SciGraph

Article Info

DATE

2015-12-14

AUTHORS

Oronzo Capozzi, Nicoletta Archidiacono, Nicola Lorusso, Roscoe Stanyon, Mariano Rocchi

ABSTRACT

Fluorescence in situ hybridization (FISH), especially chromosome painting, has been extensively exploited in the phylogenetic reconstruction of primate evolution. Although chromosome painting is a key method to map translocations, it is not effective in detecting chromosome inversions, which may be up to four times more frequent than other chromosomal rearrangements. BAC-FISH instead can economically delineate marker order and reveal intrachromosomal rearrangements. However, up to now, BAC-FISH was rarely used to study the chromosomes of New World monkeys partly due to technical difficulties. In this paper, we used BAC-FISH to disentangle the complex evolutionary history of the ancestral 14/15 association in NWMs, beginning from the squirrel monkey (Saimiri boliviensis). To improve the hybridization efficiency of BAC-FISH in NWMs, we “translated” the human BACs into Callithrix jacchus (CJA) BACs, which yielded much higher hybridization efficiencies on other NWM species than human BACs. Our results disclosed 14 synteny blocks in squirrel monkeys, 7 more than with chromosome painting. We then applied a subset of CJA BACs on six other NWM species. The comparison of the hybridization pattern of these species contained phylogenetic information to discriminate evolutionary relationships. Notably Aotus was found to share an inversion with Callithrix, thus definitely assigning the genus Aotus to Cebidae. The present study can be seen as a paradigmatic approach to investigate the phylogenetics of NWMs by molecular cytogenetics. More... »

PAGES

747-756

References to SciGraph publications

2008-06-05. Phylogenetic studies of the genus Cebus(Cebidae-Primates) using chromosome painting and G-banding in BMC ECOLOGY AND EVOLUTION

2000-05. Chromosomal homologies between humans and Cebus apella (Primates) revealed by ZOO-FISH in MAMMALIAN GENOME

2014-11-21. Centromere sliding on a mammalian chromosome in CHROMOSOMA

2014-07-20. The common marmoset genome provides insight into primate biology and evolution in NATURE GENETICS

2008-02-25. Addressing chromosome evolution in the whole-genome sequence era in CHROMOSOME RESEARCH

1999-11. Defining the ancestral karyotype of all primates by multidirectional chromosome painting between tree shrews, lemurs and humans in CHROMOSOMA

1992-03. Homologies in human and Macasa fuscata chromosomes revealed by in situ suppression hybridization with human chromosome specific DNA libraries in CHROMOSOMA

2009-10-27. Estimating the phylogeny and divergence times of primates using a supermatrix approach in BMC ECOLOGY AND EVOLUTION

2011-11-23. Molecular cytogenetic and genomic insights into chromosomal evolution in HEREDITY

2007-08-16. Phylogenomics of species from four genera of New World monkeys by flow sorting and reciprocal chromosome painting in BMC ECOLOGY AND EVOLUTION

2011-11-02. Centromere repositioning in mammals in HEREDITY

1996-06. Chromosome painting defines genomic rearrangements between red howler monkey subspecies in CHROMOSOME RESEARCH

2004-11-13. Multi-directional chromosome painting maps homologies between species belonging to three genera of New World monkeys and humans in CHROMOSOMA

2008-02-25. Primate chromosome evolution: Ancestral karyotypes, marker order and neocentromeres in CHROMOSOME RESEARCH

1997-12. Mapping chromosomal homology between humans and the black-handed spider monkey by fluorescence in situ hybridization in CHROMOSOME RESEARCH

2005-01. Mapping genomic rearrangements in titi monkeys by chromosome flow sorting and multidirectional in-situ hybridization in CHROMOSOME RESEARCH

2003-11-08. Chromosome painting in Callicebus lugens, the species with the lowest diploid number (2n=16) known in primates in CHROMOSOMA

Journal

TITLE

Chromosoma

ISSUE

VOLUME

125

Subjects

FOR: Biological Sciences

FOR: Genetics

MESH: Animals

MESH: Atelinae

MESH: Biological Evolution

MESH: Cell Line

MESH: Chromosome Inversion

MESH: Chromosome Painting

MESH: Chromosomes, Artificial, Bacterial

MESH: Evolution, Molecular

MESH: Humans

MESH: Karyotype

MESH: Phylogeny

MESH: Pitheciidae

MESH: Synteny

MESH: Translocation, Genetic

Author Affiliations

Department of Biology, University of Bari, Bari, Italy

Department of Biology, University of Florence, Florence, Italy

Identifiers

URI

http://scigraph.springernature.com/pub.10.1007/s00412-015-0565-2

DOI

http://dx.doi.org/10.1007/s00412-015-0565-2

DIMENSIONS

https://app.dimensions.ai/details/publication/pub.1031971194

PUBMED

https://www.ncbi.nlm.nih.gov/pubmed/26667930

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37	″	schema:description	Fluorescence in situ hybridization (FISH), especially chromosome painting, has been extensively exploited in the phylogenetic reconstruction of primate evolution. Although chromosome painting is a key method to map translocations, it is not effective in detecting chromosome inversions, which may be up to four times more frequent than other chromosomal rearrangements. BAC-FISH instead can economically delineate marker order and reveal intrachromosomal rearrangements. However, up to now, BAC-FISH was rarely used to study the chromosomes of New World monkeys partly due to technical difficulties. In this paper, we used BAC-FISH to disentangle the complex evolutionary history of the ancestral 14/15 association in NWMs, beginning from the squirrel monkey (Saimiri boliviensis). To improve the hybridization efficiency of BAC-FISH in NWMs, we “translated” the human BACs into Callithrix jacchus (CJA) BACs, which yielded much higher hybridization efficiencies on other NWM species than human BACs. Our results disclosed 14 synteny blocks in squirrel monkeys, 7 more than with chromosome painting. We then applied a subset of CJA BACs on six other NWM species. The comparison of the hybridization pattern of these species contained phylogenetic information to discriminate evolutionary relationships. Notably Aotus was found to share an inversion with Callithrix, thus definitely assigning the genus Aotus to Cebidae. The present study can be seen as a paradigmatic approach to investigate the phylogenetics of NWMs by molecular cytogenetics.
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44	″	schema:keywords	Aotus
45	″	″	BAC
46	″	″	BAC-FISH
47	″	″	Callithrix
48	″	″	Cebidae
49	″	″	NWM
50	″	″	NWM species
51	″	″	New World monkeys
52	″	″	World monkeys
53	″	″	approach
54	″	″	association
55	″	″	block
56	″	″	chromosomal rearrangements
57	″	″	chromosome inversions
58	″	″	chromosome painting
59	″	″	chromosomes
60	″	″	comparison
61	″	″	complex evolutionary history
62	″	″	cytogenetics
63	″	″	difficulties
64	″	″	efficiency
65	″	″	evolution
66	″	″	evolutionary history
67	″	″	evolutionary relationships
68	″	″	example
69	″	″	fluorescence
70	″	″	genus Aotus
71	″	″	high hybridization efficiency
72	″	″	history
73	″	″	human BAC
74	″	″	hybridization
75	″	″	hybridization efficiency
76	″	″	hybridization patterns
77	″	″	information
78	″	″	intrachromosomal rearrangements
79	″	″	inversion
80	″	″	karyotype evolution
81	″	″	key method
82	″	″	marker order
83	″	″	method
84	″	″	molecular cytogenetics
85	″	″	monkeys
86	″	″	order
87	″	″	painting
88	″	″	paper
89	″	″	paradigmatic approach
90	″	″	paradigmatic example
91	″	″	patterns
92	″	″	phylogenetic information
93	″	″	phylogenetic reconstruction
94	″	″	phylogenetics
95	″	″	present study
96	″	″	primate evolution
97	″	″	rearrangement
98	″	″	reconstruction
99	″	″	relationship
100	″	″	results
101	″	″	situ hybridization
102	″	″	species
103	″	″	squirrel monkeys
104	″	″	study
105	″	″	subset
106	″	″	synteny blocks
107	″	″	technical difficulties
108	″	″	time
109	″	″	translocation
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