ライフサイエンスコーパス: hominoid

1 keys) and catarrhines (Old World monkeys and hominoids).

2 ates, strepsirrhines, New World monkeys, and hominoids).

3 or if the MFS is also identifiable in other hominoids.

4 B has persisted since the common ancestor of hominoids.

5 KIR2DL4, is also common to rhesus monkey and hominoids.

6 atures that may link proconsulids with later hominoids.

7 ost extreme case of positive selection among hominoids.

8 nzee pseudogene comparison, produced U>3 for hominoids.

9 iverse set of humans but not in other extant hominoids.

10 rcopithecoids vs. more eclectic movements in hominoids.

11 e absence of comparative measures from other hominoids.

12 used and unfused morphologies in a sample of hominoids.

13 d to compare evolved energy strategies among hominoids.

14 nomic rearrangement before the divergence of hominoids.

15 alism for cercopithecoids and orthogrady for hominoids.

16 ostcranial shared derived features of extant hominoids.

17 es that place it with 'nyanzapithecine' stem hominoids.

18 slower molecular clock as compared to other hominoids.

19 nger generation time in humans than in other hominoids.

20 evolution compared to chimpanzees and other hominoids.

21 tes of single-nucleotide substitutions among hominoids.

22 rtion to the cerebellum, compared with other hominoids.

23 mark that is shared between humans and other hominoids.

24 To investigate the evolutionary context of hominoid adaptive origins, we analyzed multiple paleoenv

25 evidence bearing on proconsulids' purported hominoid affinities is further weakened by this conclusi

26 anzees, hominids (great apes and humans), or hominoids (all apes and humans), which is needed to eval

27 ever analyzed in a comparative study of the hominoid amygdala, our findings suggest that an emphasis

28 Although the generalized hominoid anatomy permits variation of locomotion: brachi

29 rtion of an Alu element in the genome of the hominoid ancestor may have contributed to tail-loss evol

30 he 26S proteasome subunit (PSMD4) genes in a hominoid ancestor.

31 ive selection, a strong episode occurring in hominoid ancestors about the time of the IgA gene duplic

32 st 25 million years of the catarrhine (i.e., hominoid and Old World monkey) evolution.

33 drocytes originated before the divergence of hominoids and catarrhine monkeys, and harbors strong sig

34 Genome-based estimates for divergence of hominoids and cercopithecoids range into the early Oligo

35 n reorganization was apparently different in hominoids and cercopithecoids, showing that brain size a

36 he morphology of the last common ancestor of hominoids and cercopithecoids, the timing of their diver

37 y has shifted its positional context between hominoids and cercopithecoids.

38 91 and KNM-BG 35250BE show similarities with hominoids and cercopithecoids.

39 ns is relatively gracile compared with other hominoids and earlier hominins.

40 Further data from hominoids and hominins are required to support the propo

41 as TBC1D3 selectively modulate signaling in hominoids and humans.

42 tem in the social/reproductive activities of hominoids and Old World monkeys (catarrhines).

43 aints since shortly before the separation of hominoids and Old World monkeys approximately 23 million

44 s of years-to date, the only such example in hominoids and Old World monkeys outside of the major his

45 e evolution of the catarrhine primates - the hominoids and Old World monkeys.

46 ble molecular phylogenies are available, the hominoids and papionins.

47 Our study reinstates a high alpha in hominoids and supports the view that DNA replication err

48 he rate of APOBEC3G gene evolution from five hominoids and two Old World monkeys.

49 t would have been partly similar with extant hominoids, and in particular with Pan (e.g., terrestrial

50 points, one each within cercopithecoids and hominoids, and tests for a statistically appropriate mod

51 Hominoid- and human-specific genes may have evolved to m

52 morphology at all ancestral nodes within the hominoid (ape and human) tree is closer to great apes th

53 eral lines of indirect evidence suggest that hominoids (apes and humans) and cercopithecoids (Old Wor

54 between the two groups of extant catarrhines-hominoids (apes and humans) and Old World monkeys-and ar

55 Phylogenetic relationships among extinct hominoids (apes and humans) are controversial due to per

56 of cercopithecoids (Old World monkeys) from hominoids (apes and humans)-is a poorly understood phase

57 ve and derived features compared with extant hominoids (apes and humans).

58 nsul these features evolved independently in hominoids (apes) and cercopithecoids and much earlier in

59 mutation rates into split times among extant hominoids (apes), given sex-specific life histories.

60 The early Pliocene African hominoid Ardipithecus ramidus was diagnosed as a having

61 Fossil hominoids are crucial to understand the selection pressu

62 Living hominoids are distinguished by upright torsos and versat

63 trees for the four extant species of African hominoids are presented, based on mtDNA control region-1

64 reproductive isolation and speciation of the hominoids as they diverged from a common ancestor.

65 patterning in ventral temporal cortex across hominoids, as well as revise the compensation theory of

66 We discuss the implications for theories on hominoid brain-size evolution.

67 ntaining processes, are exclusively found in hominoid brains while being absent from other primate br

68 n is derived with respect to earlier Miocene hominoids but is primitive with respect to the younger s

69 human HC is disproportionately large amongst hominoids, but much remains unknown at the levels of sub

70 quence data from two cercopithecoids and two hominoids by using quartet analysis.

71 ced stem catarrhine close to the base of the hominoid-cercopithecoid clade.

72 s an improvement over other estimates of the hominoid-cercopithecoid divergence because it incorporat

73 Hominoid-cercopithecoid divergence dates of 23-25 Mya fa

74 using this model of molecular evolution, the hominoid-cercopithecoid divergence is estimated to range

75 s, early catarrhine phylogeny and the age of hominoid-cercopithecoid divergence.

76 p of crown Catarrhini, and we infer that the hominoid-cercopithecoid split happened later, between 29

77 ups of anthropoid primates, the catarrhines (hominoids, cercopithecoids) and platyrrhines (ceboids),

78 lts indicate extensive local repatterning of hominoid chromosomes in euchromatic regions through a du

79 onstruct the ancestral morphology of various hominoid clades based on phylogenetically-informed maxim

80 osal of potential synapomorphies for various hominoid clades, our results confirm the relevance of ve

81 nce suggests that nyanzapithecines were stem hominoids close to the origin of extant apes, and that h

82 The hominoids, comprising apes and humans, are a group of cl

83 ver, the fossil record indicates that living hominoids constitute narrow representatives of an ancien

84 uroanatomical structures largely specific to hominoid cortex and functional properties of LPFC remain

85 nd fully extended forelimbs, as in all apes (hominoids), Danuvius combines the adaptations of bipeds

86 In this regard, the hominoids define a time frame that is particularly infor

87 on in a suite of deposits produced important hominoid dental remains of middle Pleistocene age.

88 Ubiquitin-specific protease (USP) 6 is a hominoid deubiquitinating enzyme previously implicated i

89 gests that the lineage leading to the living hominoids dispersed out of Africa about twenty million y

90 tarrhine (i.e., preceding the cercopithecoid-hominoid divergence).

91 Our results show that these proteins in hominoids do not have elevated rates of nonsynonymous su

92 Characterization of the hominoid duplicated segments reveals a strong positional

93 Among Hominoids, elaborate facial communication is accompanied

94 and KIR2DL5, have been preserved throughout hominoid evolution, and one of them, KIR2DL4, is also co

95 omy and how O. bambolii informs scenarios of hominoid evolution.

96 4 and 15) appears to have transposed late in hominoid evolution.

97 suggesting multiple origins in the course of hominoid evolution.

98 omosomal rearrangements that occurred during hominoid evolution.

99 sted an expansion relatively recently during hominoid evolution.

100 leoenvironmental proxies in conjunction with hominoid fossils from the Moroto II site in Uganda.

101 itat also has been suggested for the 6.0 Myr hominoid fossils recently recovered from Lukeino, Kenya.

102 Fossils from a large-bodied hominoid from early Miocene sediments of Uganda, along w

103 3-6.7 million years old) is the latest known hominoid from Europe, dating to approximately the diverg

104 The large-bodied hominoid from Uganda dates to at least 20.6 million year

105 ars ago (Mya) apparently after separation of hominoids from Old World (OW) monkeys.

106 Identifying stem cercopithecoids or hominoids from this period will be difficult because der

107 ily seems to be one of the highest among all hominoid gene families.

108 f genic segments during the evolution of the hominoid genome and strongly implicate GC-rich repeat el

109 a source of divergent genetic information in hominoid genomes, but their importance in physiological

110 among cercopithecoid (Old World monkey) and hominoid genomes.

111 austive BLAST searches of MCR numts in three hominoid genomes; (2) assessed numt prevalence across th

112 rth central Kenya mandates a revision of the hominoid genus Kenyapithecus, a possible early member of

113 Reorganization of the modules in the hominoid hand compared to other primates may relate to f

114 Our analyses reveal that cercopithecoids and hominoids have undergone divergent evolutionary transfor

115 any of its members are found in a variety of hominoid (humans, greater and lesser ape) genomes.

116 The evolutionary history of extant hominoids (humans and apes) remains poorly understood.

117 Rs for the natural killer and T cells of the hominoid immune system.

118 n the canine and skeletal size dimorphism in hominoids, imply that the species was not characterized

119 Despite being the most complete nonhominin hominoid in the fossil record, the O. bambolii skeleton

120 y pronounced along the catarrhine lineage to hominoids in which the nonsynonymous rate was first fast

121 at male reproductive genes evolve rapidly in hominoids is an oversimplification, a subset of proteins

122 The epidemiology of SIV infection in hominoids is characterized by low prevalences and an une

123 sent in Macaca mulatta whose divergence from hominoids is thought to have occurred at least 33 millio

124 Comparison with the predicted ancestral hominoid KIR haplotype indicates that modern gibbon KIR

125 s, New World monkeys, Old World monkeys, and hominoids, lending support to the idea that primate brai

126 ism, climbing), and the presence of a mix of hominoid-like and cercopithecoid-like traits in the axia

127 ining rates in recent Alu activity along the hominoid lineage of evolution.

128 y, the chimeric gene Tre2 exists only in the hominoid lineage of primates.

129 family evolved in the common ancestor of the hominoid lineage.

130 ore the divergence of the cercopithecoid and hominoid lineages ( approximately 30 mya).

131 to previous suggestions, that the LCA of all hominoids lived in an environment that favored a gibbon-

132 These findings suggest that the origin of hominoid locomotor versatility is associated with foragi

133 leading to the common ancestor of the modern hominoid lysozymes.

134 nder pressure from rapidly evolving viruses, hominoid MHC class I molecules also evolve rapidly, beco

135 We demonstrate that the leaf-eating hominoid Morotopithecus consumed water-stressed vegetati

136 in our knowledge of fine-scale variation in hominoid morphology, behavior, and genetics, and aspects

137 oducing selective responses to faces in this hominoid neuroanatomical structure remain unknown.

138 p to 64% higher in lineages leading from the hominoid-NWM ancestor to NWMs than to apes.

139 es have recovered Pliobates as either a stem hominoid or as a pliopithecoid stem catarrhine (i.e., pr

140 stricted to B cells from their own family of hominoids or Old World NHP, suggesting a high degree of

141 lture assays showed that Suppressyn, and its hominoid orthologs, could restrict infection by extant m

142 bxt, mimicking the expression pattern of its hominoid orthologue TBXT.

143 weaker than previously proposed, at least in hominoid PABs.

144 with an "out of Asia" origin for P. vivax as hominoid parasite.

145 head is more palmar than in all other known hominoids, permitting extreme midcarpal dorsiflexion.

146 y >1 kb in length, to accurately reconstruct hominoid phylogeny and recover the correct point of numt

147 hat played a role in the emergence of modern hominoid positional behaviors.

148 nt resided in an orthologous position in all hominoid primate genomes examined, demonstrating that th

149 Additionally, the chimpanzee is the only hominoid primate known to produce a firm copulatory plug

150 The hominoid primates (apes and humans) exhibit remarkable d

151 ed by an unusual exon-shuffling mechanism in hominoid primates and represents a key example of rapid

152 ochrome oxidase II (COII) DNA sequences from hominoid primates, including humans.

153 ng fossil apes and hominins) and reconstruct hominoid proximal femur evolution using squared-change p

154 i and therefore is a late member of the stem hominoid radiation in the East African Miocene.

155 nism that facilitated tail-loss evolution in hominoids remains unknown.

156 ars ago and thus represents the oldest known hominoid sharing these derived characters with living ap

157 A partial hominoid skeleton just older than 15 million years from

158 ting two rates of evolution, supporting the "hominoid slowdown" hypothesis.

159 ar rates comes from the primates; e.g., the "hominoid slowdown." These rate differences are hypothesi

160 and may have played a long-standing role in hominoid societies.

161 Early hominoids sought nutrition within a closed tropical fore

162 hat encoded by Tre2, may have contributed to hominoid speciation.

163 a segment of the mitochondrial genome of six hominoid species (human, common and pygmy chimpanzees, g

164 s as well as orthologous sequences for other hominoid species at one of these loci.

165 specific LCR22 variation was detected in the hominoid species supporting the hypothesis.

166 a set of 75 KIR sequences representing five hominoid species was assembled, which also included rhes

167 and divergence at semenogelin I differ among hominoid species with different mating systems.

168 and tumor suppressor genes (TSG) among seven hominoid species, including two extinct species, Neander

169 n autosomes but not on chromosome Y in other hominoid species, suggesting that it has duplicated on Y

170 romosomal-map location and copy number among hominoid species.

171 frms differ across the life span and between hominoid species.

172 ered from those acting upon the KIR of other hominoid species.

173 e duplication could be detected in non-human hominoid species.

174 ngle copy in humans but additional copies in hominoid species.

175 e reverse genomic orientation and leads to a hominoid-specific alternative splicing event.

176 Hominoid-specific brain structures are of particular imp

177 atory contribution of LTR5Hs elements to the hominoid-specific diversification of the epiblast transc

178 ate the functional effect of HERVK LTR5Hs, a hominoid-specific endogenous retrovirus, on pre-implanta

179 ence of glutamate dehydrogenase 2 (GLUD2), a hominoid-specific enzyme purportedly optimized to facili

180 xpression of glutamate dehydrogenase GDH2, a hominoid-specific enzyme with relatively restricted expr

181 This hominoid-specific oncogene arose as recently as 21-33 mi

182 TBC1D3 is a hominoid-specific oncogene encoded by a cluster of eight

183 tion of H3K9me3-dependent heterochromatin at hominoid-specific retrotransposons plays important roles

184 t the 8-cell stage, H3K9me3 reprogramming at hominoid-specific retrotransposons termed SINE-VNTR-Alu

185 potent transcription factors from binding to hominoid-specific retrotransposons-derived regulatory el

186 n development and its regulation for diverse hominoid-specific retrotransposons.

187 at the human fusiform gyrus (FG), which is a hominoid-specific structure critical for complex object

188 Hominoid spinal invagination is an embryogenetic mechani

189 of mtDNA sequence variation seen in today's hominoid taxa probably reflect historical differences in

190 ndicates sedimentary constituents, including hominoid teeth and cranial fragments accumulated from ve

191 Among the hominoid teeth excavated from S1-S3, some represent Homo

192 These results show that the hominoid temporal bone contains a strong phylogenetic si

193 Three-dimensional landmark data from the hominoid temporal bone effectively quantify the shape of

194 such substitutions in the nuclear genomes of hominoids than in the nuclear genomes of other primate a

195 istic analyses show that Pliobates is a stem hominoid that is more derived than previously described

196 Modern hominoids (that is, humans and apes) share multiple feat

197 tes, mitochondrial protein-coding genes from hominoids, the hemagglutinin (HA) gene from human influe

198 e set of Old World and New World monkeys and hominoids to identify functional regions in the human ge

199 s (New World monkeys, Old World monkeys, and hominoids) to support greater metabolic demands.

200 nd referential communication are generalized hominoid traits, given appropriate eliciting contexts.

201 everal primate species, including all extant hominoids, using magnetic resonance imaging.

202 low-value foods to test the hypothesis that hominoids vary with regards to social cohesion and inter

203 orphological analysis of human and non-human hominoids was conducted in an attempt to determine the m

204 ly when a New World monkey was compared with hominoids were the rates slightly increased in the PAR1

205 haracters but recover pliopithecoids as stem hominoids when postcranial characters are included.

206 l high levels of hand disparity among modern hominoids, which are explained by different evolutionary

207 This critical change in integration among hominoids, which is reflected in macroevolutionary diffe

208 sivalensis also supports reconstruction of a hominoid with a positional repertoire more similar to th

209 rrying out finite element simulations of the hominoid wrist during knuckle-walking by virtually gener

210 ypothesis is the role of the centrale in the hominoid wrist, since the fusion of this bone with the s