A citation-based method for searching scientific literature

Ryosuke Ohsawa, Ryoichiro Kageyama. Brain Res 2008
Times Cited: 118







List of co-cited articles
1082 articles co-cited >1



Times Cited
  Times     Co-cited
Similarity




Pax6 is required for the multipotent state of retinal progenitor cells.
T Marquardt, R Ashery-Padan, N Andrejewski, R Scardigli, F Guillemot, P Gruss. Cell 2001
660
25

Math5 is required for retinal ganglion cell and optic nerve formation.
N L Brown, S Patel, J Brzezinski, T Glaser. Development 2001
363
25


Requirement for math5 in the development of retinal ganglion cells.
S W Wang, B S Kim, K Ding, H Wang, D Sun, R L Johnson, W H Klein, L Gan. Genes Dev 2001
360
19

From progenitors to differentiated cells in the vertebrate retina.
Michalis Agathocleous, William A Harris. Annu Rev Cell Dev Biol 2009
167
19

Individual retinal progenitor cells display extensive heterogeneity of gene expression.
Jeffrey M Trimarchi, Michael B Stadler, Constance L Cepko. PLoS One 2008
118
18

Ocular retardation mouse caused by Chx10 homeobox null allele: impaired retinal progenitor proliferation and bipolar cell differentiation.
M Burmeister, J Novak, M Y Liang, S Basu, L Ploder, N L Hawes, D Vidgen, F Hoover, D Goldman, V I Kalnins,[...]. Nat Genet 1996
407
18

Notch 1 inhibits photoreceptor production in the developing mammalian retina.
Ashutosh P Jadhav, Heather A Mason, Constance L Cepko. Development 2006
158
18

Cell fate determination in the vertebrate retina.
C L Cepko, C P Austin, X Yang, M Alexiades, D Ezzeddine. Proc Natl Acad Sci U S A 1996
747
18

Otx2 homeobox gene controls retinal photoreceptor cell fate and pineal gland development.
Akihiro Nishida, Akiko Furukawa, Chieko Koike, Yasuo Tano, Shinichi Aizawa, Isao Matsuo, Takahisa Furukawa. Nat Neurosci 2003
398
17

Notch1 functions to suppress cone-photoreceptor fate specification in the developing mouse retina.
Orly Yaron, Chen Farhy, Till Marquardt, Meredithe Applebury, Ruth Ashery-Padan. Development 2006
130
17

Foxn4 controls the genesis of amacrine and horizontal cells by retinal progenitors.
Shengguo Li, Zeqian Mo, Xuejie Yang, Sandy M Price, Michael M Shen, Mengqing Xiang. Neuron 2004
177
17

Retinal cell fate determination and bHLH factors.
Jun Hatakeyama, Ryoichiro Kageyama. Semin Cell Dev Biol 2004
191
17

Math5 determines the competence state of retinal ganglion cell progenitors.
Zhiyong Yang, Kan Ding, Ling Pan, Min Deng, Lin Gan. Dev Biol 2003
197
16

Ptf1a determines horizontal and amacrine cell fates during mouse retinal development.
Yoshio Fujitani, Shuko Fujitani, Huijun Luo, Feng Qiu, Jared Burlison, Qiaoming Long, Yoshiya Kawaguchi, Helena Edlund, Raymond J MacDonald, Takahisa Furukawa,[...]. Development 2006
165
15

Islet-1 controls the differentiation of retinal bipolar and cholinergic amacrine cells.
Yasser Elshatory, Drew Everhart, Min Deng, Xiaoling Xie, Robert B Barlow, Lin Gan. J Neurosci 2007
132
15

Math3 and NeuroD regulate amacrine cell fate specification in the retina.
Tomoyuki Inoue, Masato Hojo, Yasumasa Bessho, Yasuo Tano, Jacqueline E Lee, Ryoichiro Kageyama. Development 2002
208
14

Math5 encodes a murine basic helix-loop-helix transcription factor expressed during early stages of retinal neurogenesis.
N L Brown, S Kanekar, M L Vetter, P K Tucker, D L Gemza, T Glaser. Development 1998
248
14

Requirement for Bhlhb5 in the specification of amacrine and cone bipolar subtypes in mouse retina.
Liang Feng, Xiaoling Xie, Pushkar S Joshi, Zhiyong Yang, Koji Shibasaki, Robert L Chow, Lin Gan. Development 2006
102
14

rax, Hes1, and notch1 promote the formation of Müller glia by postnatal retinal progenitor cells.
T Furukawa, S Mukherjee, Z Z Bao, E M Morrow, C L Cepko. Neuron 2000
378
14

Timing and topography of cell genesis in the rat retina.
David H Rapaport, Lily L Wong, Eric D Wood, Douglas Yasumura, Matthew M LaVail. J Comp Neurol 2004
263
14


Roles of homeobox and bHLH genes in specification of a retinal cell type.
J Hatakeyama, K Tomita, T Inoue, R Kageyama. Development 2001
186
13

Reconstruction of rat retinal progenitor cell lineages in vitro reveals a surprising degree of stochasticity in cell fate decisions.
Francisco L A F Gomes, Gen Zhang, Felix Carbonell, José A Correa, William A Harris, Benjamin D Simons, Michel Cayouette. Development 2011
106
13

SOX2 is a dose-dependent regulator of retinal neural progenitor competence.
Olena V Taranova, Scott T Magness, B Matthew Fagan, Yongqin Wu, Natalie Surzenko, Scott R Hutton, Larysa H Pevny. Genes Dev 2006
378
12




Transcriptional regulation of photoreceptor development and homeostasis in the mammalian retina.
Anand Swaroop, Douglas Kim, Douglas Forrest. Nat Rev Neurosci 2010
319
12

Prox1 function controls progenitor cell proliferation and horizontal cell genesis in the mammalian retina.
Michael A Dyer, Frederick J Livesey, Constance L Cepko, Guillermo Oliver. Nat Genet 2003
292
11


Cone contacts, mosaics, and territories of bipolar cells in the mouse retina.
Heinz Wässle, Christian Puller, Frank Müller, Silke Haverkamp. J Neurosci 2009
274
11

ISL1 and BRN3B co-regulate the differentiation of murine retinal ganglion cells.
Ling Pan, Min Deng, Xiaoling Xie, Lin Gan. Development 2008
127
11

Neurog2 controls the leading edge of neurogenesis in the mammalian retina.
Robert B Hufnagel, Tien T Le, Ashley L Riesenberg, Nadean L Brown. Dev Biol 2010
67
16

Rbpj cell autonomous regulation of retinal ganglion cell and cone photoreceptor fates in the mouse retina.
Amy N Riesenberg, Zhenyi Liu, Raphael Kopan, Nadean L Brown. J Neurosci 2009
73
15

Nrl is required for rod photoreceptor development.
A J Mears, M Kondo, P K Swain, Y Takada, R A Bush, T L Saunders, P A Sieving, A Swaroop. Nat Genet 2001
652
10

Influences on neural lineage and mode of division in the zebrafish retina in vivo.
Lucia Poggi, Marta Vitorino, Ichiro Masai, William A Harris. J Cell Biol 2005
128
10

Requirement of multiple basic helix-loop-helix genes for retinal neuronal subtype specification.
Tadamichi Akagi, Tomoyuki Inoue, Goichi Miyoshi, Yasumasa Bessho, Masayo Takahashi, Jacqueline E Lee, François Guillemot, Ryoichiro Kageyama. J Biol Chem 2004
105
10

A gene network downstream of transcription factor Math5 regulates retinal progenitor cell competence and ganglion cell fate.
Xiuqian Mu, Xueyao Fu, Hongxia Sun, Phillip D Beremand, Terry L Thomas, William H Klein. Dev Biol 2005
101
10

Gene regulation logic in retinal ganglion cell development: Isl1 defines a critical branch distinct from but overlapping with Pou4f2.
Xiuqian Mu, Xueyao Fu, Phillip D Beremand, Terry L Thomas, William H Klein. Proc Natl Acad Sci U S A 2008
103
10

Retinal ganglion cell-derived sonic hedgehog locally controls proliferation and the timing of RGC development in the embryonic mouse retina.
Yaping Wang, Gabriel D Dakubo, Sherry Thurig, Chantal J Mazerolle, Valerie A Wallace. Development 2005
155
10

Notch activity permits retinal cells to progress through multiple progenitor states and acquire a stem cell property.
Ashutosh P Jadhav, Seo-Hee Cho, Constance L Cepko. Proc Natl Acad Sci U S A 2006
97
10

MATH5 controls the acquisition of multiple retinal cell fates.
Liang Feng, Zheng-hua Xie, Qian Ding, Xiaoling Xie, Richard T Libby, Lin Gan. Mol Brain 2010
59
16

How variable clones build an invariant retina.
Jie He, Gen Zhang, Alexandra D Almeida, Michel Cayouette, Benjamin D Simons, William A Harris. Neuron 2012
133
10

Crx, a novel Otx-like paired-homeodomain protein, binds to and transactivates photoreceptor cell-specific genes.
S Chen, Q L Wang, Z Nie, H Sun, G Lennon, N G Copeland, D J Gilbert, N A Jenkins, D J Zack. Neuron 1997
536
9


Conserved regulatory sequences in Atoh7 mediate non-conserved regulatory responses in retina ontogenesis.
Dorota Skowronska-Krawczyk, Florence Chiodini, Martin Ebeling, Christine Alliod, Adam Kundzewicz, Diogo Castro, Marc Ballivet, François Guillemot, Lidia Matter-Sadzinski, Jean-Marc Matter. Development 2009
29
31

Math5 is required for both early retinal neuron differentiation and cell cycle progression.
Tien T Le, Emily Wroblewski, Sima Patel, Amy N Riesenberg, Nadean L Brown. Dev Biol 2006
78
11


Co-cited is the co-citation frequency, indicating how many articles cite the article together with the query article. Similarity is the co-citation as percentage of the times cited of the query article or the article in the search results, whichever is the lowest. These numbers are calculated for the last 100 citations when articles are cited more than 100 times.