ライフサイエンスコーパス: pallium

1 (nest pallium), and the arcopallium (arched pallium).

2 telencephalon (notably its dorsal part, the pallium).

3 hese abilities require dorsal telencephalon (pallium).

4 ischemic penumbra regions (e.g. hippocampus, pallium).

5 on and other higher order areas of the avian pallium.

6 lls with a rostral phenotype from the dorsal pallium.

7 extends from the subpallium into the dorsal pallium.

8 for CR cells on the edges of the developing pallium.

9 r include labeled cell bodies in the lateral pallium.

10 l) and medial (Dm) divisions of the goldfish pallium.

11 is restricted to regions close to the medial pallium.

12 ly dorsal thalamic nucleus projecting to the pallium.

13 ested to derive from ventral portions of the pallium.

14 entralmost pallial region, i.e., the ventral pallium.

15 re dispersed in the hypothalamus and ventral pallium.

16 traversing the basal ganglia, thalamus, and pallium.

17 orming a short recurrent pathway through the pallium.

18 synapse loss predominated in the dorsomedial pallium.

19 re closely related to neurons in the ventral pallium.

20 typically associated with the telencephalic pallium.

21 ludes a medial, dorsal, lateral, and ventral pallium.

22 ing functional properties in the adult avian pallium.

23 reciprocal changes in synapse numbers in the pallium.

24 f neuronal types between mammalian and avian pallium.

25 , with memory formation in any region of the pallium.

26 oligodendrocyte lineage cells in the dorsal pallium.

27 ly tested predictions derived from mammalian pallium.

28 rto was considered to arise from the lateral pallium.

29 a hippocampal formation across the goldfish pallium.

30 into a smaller ventral pallium and a lateral pallium.

31 sal pallial part, not of the classic lateral pallium.

32 the macroarchitecture of the zebrafish adult pallium.

33 anding the organization and evolution of the pallium.

34 onsidered homologous to medial and/or dorsal pallium.

35 sition within the developing chicken lateral pallium.

36 general characteristic of the avian sensory pallium.

37 one of the main components of the sauropsid pallium.

38 ine a comprehensive regional fate map of the pallium.

39 ingless, later foxg1 expression and a larger pallium.

40 5a in the subpallium and tbr1, neurod in the pallium.

41 input and output pathways of the gymnotiform pallium.

42 erstood, particularly as regards the roof or pallium.

43 not the case with RG cells isolated from the pallium.

44 rior neural plate that will give rise to the pallium.

45 imary sensory input population (intercalated pallium); 2) a secondary intrapallial population (nidopa

46 ions (CMM, dNCM and vNCM) of the caudomedial pallium, a higher order auditory region.

47 1 and Neurog2 are coexpressed in the ventral pallium, a progenitor pool that first gives rise to Caja

48 over that distinct subdivisions in the avian pallium above and below the ventricle and the associated

49 rog2 have redundant functions in the ventral pallium, acting in two phases to first specify a CR cell

50 Watson/Puelles model into a smaller ventral pallium and a lateral pallium.

51 ineated nine main neuronal cell types in the pallium and eight in the subpallium and nominated novel

52 t, Tbr2 is expressed in all of the zebrafish pallium and in a restricted zone of the ventral subpalli

53 ventricular and subventricular zones of the pallium and migrate along radial glia fibers to reach th

54 We identify the boundary between the pallium and subpallium based on the complementary expres

55 eural progenitors, mimicking human forebrain pallium and subpallium development.

56 s, in distinct regions of the telencephalon (pallium and subpallium), diencephalon, mesencephalon, hi

57 hes, but cholinergic-positive neurons in the pallium and subpallium, and in the thalamus and cerebell

58 hat mimic development of the human forebrain pallium and subpallium, respectively.

59 elencephalon has two major subdivisions, the pallium and subpallium.

60 or a marked regionalization of the reptilian pallium and subpallium.

61 tures of their embryonic site of origin, the pallium and subpallium.

62 ther, the septal nuclei derive from both the pallium and subpallium.

63 of these Emx1-lineage cells originate in the pallium and subsequently migrate to the developing stria

64 central (DC), and dorsal (DD) regions of the pallium and the intermediate region between DL and DC (D

65 bers were observed in both the telencephalic pallium and the subpallium, in the thalamus and pretectu

66 ts adult derivatives develop from the dorsal pallium and ventral subpallium.

67 , an effect that was localized in the dorsal pallium and was negatively associated with responsivenes

68 the striatum, the D1D and D3 throughout the pallium and within the mesopallium, respectively, and th

69 l boundary, which separates the dorsal (i.e. pallium) and ventral (i.e. subpallium) telencephalon.

70 lium (middle pallium), the nidopallium (nest pallium), and the arcopallium (arched pallium).

71 ated in the caudal pole of the telencephalic pallium, and a cell population that travels from the pre

72 c cells were observed in the olfactory bulb, pallium, and preoptic area of the telencephalon, and the

73 hy of secondary olfactory projections to the pallium are critical in evaluating these hypotheses, but

74 p53 in causing DNA damage in the developing pallium, as detection of yH2aX+ was delayed in the dKO.

75 Nr4a2-labeled subplate cells in the lateral pallium at the site of the future insular cortex.

76 te that, upon mechanical injury to the adult pallium, axolotls can regenerate several of the populati

77 all along the urodele CNS (olfactory bulbs, pallium, basal ganglia, diencephalon, mesencephalic tegm

78 cal motor pathway and an anterior forebrain (pallium-basal ganglia-thalamo-pallial) loop.

79 we show that GINs migrate normally into the pallium, but fail to acquire proper layer position.

80 t of the claustrum primordium in the lateral pallium, but they migrate ventrally to reach the ventral

81 rons in the zebra finch auditory association pallium (calmodulin-dependent kinase alpha [CaMKIIa] and

82 he minor spliceosome in the developing mouse pallium, causing microcephaly.

83 4-dimensional (3D + birthdating time) map of pallium construction in the adult teleost zebrafish.

84 This simple mode of pallium construction shares distinct traits with pallial

85 t from the basal ganglia, and input from the pallium (cortex in mammals) and torus semicircularis.

86 neurons receive direct projections from the pallium (cortex in mammals), which can increase the GPh

87 minantly in the dorsocentral division of the pallium (DC); the dorsolateral division of the pallium (

88 e connectivity of the subdivisions of dorsal pallium (DD) of an electric gymnotiform fish, Apteronotu

89 they migrate ventrally to reach the ventral pallium deep to the piriform cortex at E14.5 in the mous

90 AACs are deployed across essentially all the pallium-derived brain structures, including not only the

91 hippocampal formation, but also the lateral pallium-derived claustrum-insular complex, and the ventr

92 d claustrum-insular complex, and the ventral pallium-derived extended amygdaloid complex and olfactor

93 dorsal pallium-derived neocortex and medial pallium-derived hippocampal formation, but also the late

94 in structures, including not only the dorsal pallium-derived neocortex and medial pallium-derived hip

95 nterior frontal cortex of mice with a dorsal pallium-derived, conditional knock-out (cKO) of Met.

96 llium (DC); the dorsolateral division of the pallium (DL) contained only weakly labeled neurons.

97 jor pathways are recursive: the dorsolateral pallium (DL) projects strongly to DDi, with lesser input

98 Apteronotus leptorhynchus, the dorsolateral pallium (DL) receives diencephalic inputs representing e

99 nections of DD are entirely intrinsic to the pallium: DL projects to DD (glutamatergic) and DD feeds

100 ing dorsal telencephalon with, in the medial pallium, Dmrta2 but not Emx2 expressed in the developing

101 anscription factor largely restricted to the pallium during development.

102 AD1 cell types in avian auditory association pallium exhibit distinct intrinsic physiological paramet

103 Here, we show that the avian auditory pallium exhibits the same information-processing princip

104 The lizard medial pallium, expressing all genes, includes the medial and d

105 The ventral pallium, expressing Lhx9, but not Emx1, gives rise to th

106 Furthermore, like the mammalian pallium, expression in the ventral pallial subdivisions

107 , the hyperstriatum accessorium (HA) and the pallium externum (PE).

108 subdivisions in the dorsal and ventral avian pallium, forming mirror images to each other.

109 ound that Dbx1-positive cells of the ventral pallium generate the excitatory neurons of the basolater

110 now newly propose that the mammalian ventral pallium gives rise not only to all of the pallial amygda

111 nown connectivity, we propose that the avian pallium has four major cell populations similar to those

112 sites of activity differences, including the pallium, hypothalamus, and tectum.

113 region exclusively connecting midbrain with pallium, implements a mixed selectivity strategy to enco

114 till uncertain for most of the telencephalic pallium in birds and thus the new pallial terminology is

115 had the tendency to descend into the ventral pallium in large aberrant fascicles.

116 s known about the development of the lateral pallium in mammals.

117 The region designated as the ventral pallium in the initial quadripartite model should theref

118 dopamine regulates learning in the auditory pallium, in part by interacting with local neuroestradio

119 the median ganglionic eminence (MGE) to the pallium, including the hippocampus.

120 In mammals, the pallium is a layered mixture of excitatory and inhibitor

121 The mouse pallium is apt to be reexamined in this context, due to

122 In addition, the avian auditory pallium is composed of adjacent information-processing r

123 By contrast, the salamander dorsal pallium is devoid of cellular and molecular characterist

124 In contrast, the teleost pallium is not well understood and its relation to that

125 igrating Nr4a2-negative cells in the ventral pallium; it is therefore developmentally distinct from t

126 ered a most ventrolateral part of the dorsal pallium (its ventrolateral subdivision).

127 tinct regions: (1) descending input from the pallium itself (dorsomedial and dorsocentral subdivision

128 connections between the accumbens and medial pallium just dorsal to it suggest a column-like organiza

129 brain areas including the dorsal and medial pallium, lateral and medial septum, bed nucleus of the s

130 e development of the progenitor zones in the pallium, lateral ganglionic eminence (LGE) and medial ga

131 ic ablation of MET signaling in mouse dorsal pallium leads to altered neuronal morphology indicative

132 Innovations in the pallium likely facilitated the evolution of advanced cog

133 Sensory-evoked potentials in this fish pallium may be more segregated than in elasmobranchs and

134 First, the avian medial pallium may correspond to part of the mammalian prefront

135 fly explore how far this theory may apply to pallium models proposed recently for sauropsids.

136 ed, with the highest densities in the medial pallium (mp; homolog of the mammalian hippocampus), accu

137 mygdalar, claustral, and septal areas of the pallium, nuclear in structure.

138 Broca, preoptic area, hypothalamus, rostral pallium, nucleus accumbens, ventral pallidum, and bed nu

139 septum; amygdala; nucleus accumbens; ventral pallium; nucleus basalis Meynert; bed nucleus of the str

140 emonstration of steroid concentration in the pallium of a teleost forebrain.

141 The quadripartite model of the telencephalic pallium of amniotes offered by the Puelles school includ

142 wirelessly recorded neural activity from the pallium of freely swimming Gymnotus.

143 gies between DL and DC and medial and dorsal pallium of tetrapods, respectively.

144 The caudomedial pallium of the male budgerigar may have functional subdi

145 sic connections of the dorsal telencephalon (pallium) of gymnotiform fish.

146 In the dorsal telencephalon (pallium) of vertebrates, it remains unresolved which anc

147 al and organizational model of the zebrafish pallium-one which is the result of a complex outward-inw

148 addition there was almost no CARTp-ir in the pallium or the hippocampal formation, and little CARTp-i

149 and the VLS receives inputs from the lateral pallium-originated areas (e.g., the insula) [5, 6].

150 The VMS receives inputs from medial pallium-originated limbic structures (e.g., the medial p

151 e report that the germinal zone of the adult pallium originates from two distinct subtypes of embryon

152 the lateral septum, amygdala pars lateralis, pallium, preoptic area, hypothalamus, and dorsal mesence

153 medial amygdala, septal territories, medial pallium, preoptic area, lateral hypothalamus, thalamus,

154 We found that the avian pallium shares most inhibitory neuron types with other a

155 auditory association in the songbird sensory pallium.SIGNIFICANCE STATEMENTOur key finding is that au

156 erminate in all subpallial nuclei and in the pallium: sparsely in the medial pallial division (Dm); h

157 r of the olfactory bulbs, dorsal and lateral pallium, striatum, various subfields of the amygdala, be

158 pulations of many CNS regions, including the pallium, subpallium, hypothalamus, diencephalon, optic t

159 a lens to understand the common features of pallium that are important for advanced cognition.

160 x [5,6]; rather, they possess a neuron-dense pallium that is organized in clusters, in contrast to th

161 espectively) the hyperpallium (hypertrophied pallium), the mesopallium (middle pallium), the nidopall

162 ertrophied pallium), the mesopallium (middle pallium), the nidopallium (nest pallium), and the arcopa

163 progenitor domains in the telencephalon: the pallium, the major source of excitatory neurons, and the

164 ypothalamus, amygdala homologs of the dorsal pallium, the pineal organ, the inner ear, the pituitary,

165 communication information is conveyed to the pallium through complex indirect pathways that originate

166 an basal ganglia were renamed as part of the pallium, using prefixes that retain most established abb

167 at immediately flank the PSB are the ventral pallium (VP) and the dorsal lateral ganglionic eminence

168 ata indicate that progenitors in the ventral pallium (VP) contribute projection neurons to the LA and

169 Thus, the region of the lateral pallium was misidentified in the quadripartite model, as

170 We show that the transcriptome of the dKO pallium was more similar to the control compared with th

171 earance of TH-ir cells in the telencephalon (pallium) was rather late (stage [S]31) with respect to t

172 M), a secondary auditory region of the avian pallium, was necessary for maintaining auditory memories

173 brains showed hemispheric asymmetries in the pallium, whereas females had higher interhemispheric con

174 cipient sensory neurons of the telencephalic pallium, whereas high egr1 upregulation occurred only in

175 atory neurons derive from progenitors in the pallium, whereas inhibitory neurons originate from proge

176 ain has a "limbic loop" involving the medial pallium, which also receives input from the avian equiva

177 the number of synapses in the ventrolateral pallium, which contains neurons active during memory for

178 s in the spatial patterns of synapses in the pallium, which contains the equivalent of the mammalian

179 a, and may belong to a distinct dorsolateral pallium, which extends from rostral to caudal levels.

180 The pallium, which primarily consists of glutamatergic corti

181 luence hypotheses on homologies of the avian pallium with other vertebrates.