{"PubmedArticle":{"MedlineCitation":{"@attributes":{"Status":"MEDLINE","Owner":"NLM","IndexingMethod":"Manual"},"PMID":{"@attributes":{"Version":"1"},"@text":"21698205"},"DateCompleted":{"Year":"2011","Month":"11","Day":"07"},"DateRevised":{"Year":"2021","Month":"10","Day":"20"},"Article":{"@attributes":{"PubModel":"Print-Electronic"},"Journal":{"ISSN":{"@attributes":{"IssnType":"Electronic"},"@text":"1932-6203"},"JournalIssue":{"@attributes":{"CitedMedium":"Internet"},"Volume":"6","Issue":"6","PubDate":{"Year":"2011"}},"Title":"PloS one","ISOAbbreviation":"PLoS One"},"ArticleTitle":"The lineage contribution and role of Gbx2 in spinal cord development.","Pagination":{"StartPage":"e20940","MedlinePgn":"e20940"},"ELocationID":[{"@attributes":{"EIdType":"pii","ValidYN":"Y"},"@text":"e20940"},{"@attributes":{"EIdType":"doi","ValidYN":"Y"},"@text":"10.1371\/journal.pone.0020940"}],"Abstract":{"AbstractText":[{"@attributes":{"Label":"BACKGROUND","NlmCategory":"BACKGROUND"},"@text":"Forging a relationship between progenitors with dynamically changing gene expression and their terminal fate is instructive for understanding the logic of how cell-type diversity is established. The mouse spinal cord is an ideal system to study these mechanisms in the context of developmental genetics and nervous system development. Here we focus on the Gastrulation homeobox 2 (Gbx2) transcription factor, which has not been explored in spinal cord development."},{"@attributes":{"Label":"METHODOLOGY\/PRINCIPAL FINDINGS","NlmCategory":"RESULTS"},"@text":"We determined the molecular identity of Gbx2-expressing spinal cord progenitors. We also utilized genetic inducible fate mapping to mark the Gbx2 lineage at different embryonic stages in vivo in mouse. Collectively, we uncover cell behaviors, cytoarchitectonic organization, and the terminal cell fate of the Gbx2 lineage. Notably, both ventral motor neurons and interneurons are derived from the Gbx2 lineage, but only during a short developmental period. Short-term fate mapping during mouse spinal cord development shows that Gbx2 expression is transient and is extinguished ventrally in a rostral to caudal gradient. Concomitantly, a permanent lineage restriction boundary ensures that spinal cord neurons derived from the Gbx2 lineage are confined to a dorsal compartment that is maintained in the adult and that this lineage generates inhibitory interneurons of the spinal cord. Using lineage tracing and molecular markers to follow Gbx2-mutant cells, we show that the loss of Gbx2 globally affects spinal cord patterning including the organization of interneuron progenitors. Finally, long-term lineage analysis reveals that the presence and timing of Gbx2 expression in interneuron progenitors results in the differential contribution to subtypes of terminally differentiated interneurons in the adult spinal cord."},{"@attributes":{"Label":"CONCLUSIONS\/SIGNIFICANCE","NlmCategory":"CONCLUSIONS"},"@text":"We illustrate the complex cellular nature of Gbx2 expression and lineage contribution to the mouse spinal cord. In a broader context, this study provides a direct link between spinal cord progenitors undergoing dynamic changes in molecular identity and terminal neuronal fate."}]},"AuthorList":{"@attributes":{"CompleteYN":"Y"},"Author":[{"@attributes":{"ValidYN":"Y"},"LastName":"Luu","ForeName":"Brian","Initials":"B","AffiliationInfo":[{"Affiliation":"Division of Biology and Medicine, Department of Molecular Biology, Cell Biology and Biochemistry, Brown University, Providence, Rhode Island, United States of America."}]},{"@attributes":{"ValidYN":"Y"},"LastName":"Ellisor","ForeName":"Debra","Initials":"D"},{"@attributes":{"ValidYN":"Y"},"LastName":"Zervas","ForeName":"Mark","Initials":"M"}]},"Language":["eng"],"PublicationTypeList":{"PublicationType":[{"@attributes":{"UI":"D016428"},"@text":"Journal Article"},{"@attributes":{"UI":"D013485"},"@text":"Research Support, Non-U.S. Gov't"}]},"ArticleDate":[{"@attributes":{"DateType":"Electronic"},"Year":"2011","Month":"06","Day":"16"}]},"MedlineJournalInfo":{"Country":"United States","MedlineTA":"PLoS One","NlmUniqueID":"101285081","ISSNLinking":"1932-6203"},"ChemicalList":{"Chemical":[{"RegistryNumber":"0","NameOfSubstance":{"@attributes":{"UI":"C513182"},"@text":"Gbx2 protein, mouse"}},{"RegistryNumber":"0","NameOfSubstance":{"@attributes":{"UI":"D018398"},"@text":"Homeodomain Proteins"}}]},"CitationSubset":["IM"],"MeshHeadingList":{"MeshHeading":[{"DescriptorName":{"@attributes":{"UI":"D000818","MajorTopicYN":"N"},"@text":"Animals"}},{"DescriptorName":{"@attributes":{"UI":"D019070","MajorTopicYN":"Y"},"@text":"Cell Lineage"}},{"DescriptorName":{"@attributes":{"UI":"D018398","MajorTopicYN":"N"},"@text":"Homeodomain Proteins"},"QualifierName":[{"@attributes":{"UI":"Q000502","MajorTopicYN":"Y"},"@text":"physiology"}]},{"DescriptorName":{"@attributes":{"UI":"D051379","MajorTopicYN":"N"},"@text":"Mice"}},{"DescriptorName":{"@attributes":{"UI":"D013116","MajorTopicYN":"N"},"@text":"Spinal Cord"},"QualifierName":[{"@attributes":{"UI":"Q000166","MajorTopicYN":"N"},"@text":"cytology"},{"@attributes":{"UI":"Q000254","MajorTopicYN":"Y"},"@text":"growth & development"}]}]},"CoiStatement":"Competing Interests: <\/b>The authors have declared that no competing interests exist."},"PubmedData":{"History":{"PubMedPubDate":[{"@attributes":{"PubStatus":"received"},"Year":"2010","Month":"9","Day":"21"},{"@attributes":{"PubStatus":"accepted"},"Year":"2011","Month":"5","Day":"16"},{"@attributes":{"PubStatus":"entrez"},"Year":"2011","Month":"6","Day":"24","Hour":"6","Minute":"0"},{"@attributes":{"PubStatus":"pubmed"},"Year":"2011","Month":"6","Day":"24","Hour":"6","Minute":"0"},{"@attributes":{"PubStatus":"medline"},"Year":"2011","Month":"11","Day":"8","Hour":"6","Minute":"0"},{"@attributes":{"PubStatus":"pmc-release"},"Year":"2011","Month":"6","Day":"16"}]},"PublicationStatus":"ppublish","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"21698205"},{"@attributes":{"IdType":"pmc"},"@text":"PMC3116860"},{"@attributes":{"IdType":"doi"},"@text":"10.1371\/journal.pone.0020940"},{"@attributes":{"IdType":"pii"},"@text":"PONE-D-10-02515"}]},"ReferenceList":[{"Reference":[{"Citation":"Caspary T, Anderson KV. Patterning cell types in the dorsal spinal cord: what the mouse mutants say. Nat Rev Neurosci. 2003;4:289\u2013297.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12671645"}]}},{"Citation":"Ladle DR, Pecho-Vrieseling E, Arber S. Assembly of motor circuits in the spinal cord: driven to function by genetic and experience-dependent mechanisms. Neuron. 2007;56:270\u2013283.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"17964245"}]}},{"Citation":"Ramon y Cajal S. Histology of the Nervous system. New York: Oxford University Press Inc; 1995."},{"Citation":"Paxinos G. The Rat Nervous System. In: Paxinos G, editor. London: Elsevier; 2004."},{"Citation":"Gilman S, Newman SW. Essentials of Clinical Neuroanatomy and Neurophysiology. F.A. Davis Company 1992"},{"Citation":"Dasen JS, Jessell Hox networks and the origins of motor neuron diversity. Curr Top Dev Biol. 2009;88:169\u2013200.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"19651305"}]}},{"Citation":"Helms AW, Johnson JE. Specification of dorsal spinal cord interneurons. Curr Opin Neurobiol. 2003;13:42\u201349.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12593981"}]}},{"Citation":"Briscoe J, Pierani A, Jessell TM, Ericson J. A homeodomain protein code specifies progenitor cell identity and neuronal fate in the ventral neural tube. Cell. 2000;101:435\u2013445.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"10830170"}]}},{"Citation":"Ericson J, Rashbass P, Schedl A, Brenner-Morton S, Kawakami A, et al. Pax6 controls progenitor cell identity and neuronal fate in response to graded Shh signaling. Cell. 1997;90:169\u2013180.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9230312"}]}},{"Citation":"Jessell T. Neuronal Specfication in the Spinal Cord: Inductive Signals and Transcriptional Codes. Nature Reviews Genetics. 2000;1:20\u201329.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"11262869"}]}},{"Citation":"Alvarez-Medina R, Cayuso J, Okubo T, Takada S, Mart\u00ed E. Wnt canonical pathway restricts graded Shh\/Gli patterning activity through the regulation of Gli3 expression. Development. 2008;135:237\u2013247.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"18057099"}]}},{"Citation":"Briscoe J, EJ Specification of neuronal fates in the ventral neural tube. Curr Opin Neurobiol. 2001;11:43\u201349.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"11179871"}]}},{"Citation":"Lee S, Pfaff S. Transcriptional networks regulating neuronal identity in the developing spinal cord. Nature Neuroscience Reviews. 2001;4:1183\u20131191.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"11687828"}]}},{"Citation":"Agalliu D, Takada S, Agalliu I, McMahon AP, Jessell TM. Motor neurons with axial muscle projections specified by Wnt4\/5 signaling. Neuron. 2009;61:708\u2013720.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2741579"},{"@attributes":{"IdType":"pubmed"},"@text":"19285468"}]}},{"Citation":"Dasen J. A Hox Regulatory Network Establishes Motor Neuron Pool Identity and Target-Muscle Connectivity. Cell. 2005;123:477\u2013491.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"16269338"}]}},{"Citation":"Shirasaki R, Pfaff SL. Transcriptional codes and the control of neuronal identity. Annu Rev Neurosci. 2002;25:251\u2013281.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12052910"}]}},{"Citation":"Lee S, Lee B, Joshi K, Pfaff SL, Lee JW, et al. A regulatory network to segregate the identity of neuronal subtypes. Dev Cell. 2008;14:877\u2013889.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC3071743"},{"@attributes":{"IdType":"pubmed"},"@text":"18539116"}]}},{"Citation":"Chapman G, Remiszewski JL, Webb GC, Schulz TC, Bottema CD, et al. The Mouse Homeobox Gene, Gbx2: Genomic Organization and Expression in Pluripotent Cells in Vitro and in Vivo. Genomics. 1997;46:223\u2013233.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9417909"}]}},{"Citation":"Bouillet P, Chazaud C, Oulad-Abdelghani M, Doll\u00e9 P, Chambon P. Sequence and expression pattern of the Stra7 (Gbx-2) homeobox-containing gene induced by retinoic acid in P19 embryonal carcinoma cells. Dev Dyn. 1995;204:372\u2013382.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"8601031"}]}},{"Citation":"Li JY, Joyner AL. Otx2 and Gbx2 are required for refinement and not induction of mid- hindbrain gene expression. Development. 2001;128:4979\u2013491.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"11748135"}]}},{"Citation":"Wassarman KM, Lewandoski M, Campbell K, Joyner AL, Rubenstein JL, et al. Specification of the anterior hindbrain and establishment of a normal mid\/hindbrain organizer is dependent on Gbx2 gene function. Development. 1997;124:2923\u2013234.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9247335"}]}},{"Citation":"John A, Wildner H, Britsch S. The homeodomain transcription factor Gbx1 identifies a subpopulation of late-born GABAergic interneurons in the developing dorsal spinal cord. Dev Dyn. 2005;234:767\u2013771.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"16193514"}]}},{"Citation":"Li JY, Lao Z, Joyner AL. Changing requirements for Gbx2 in development of the cerebellum and maintenance of the mid\/hindbrain organizer. Neuron. 2002;36:31\u201343.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12367504"}]}},{"Citation":"Chen L, Guo Q, Li JY. Transcription factor Gbx2 acts cell-nonautonomously to regulate the formation of lineage-restriction boundaries of the thalamus. Development. 2009;136:1317\u20131326.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2687463"},{"@attributes":{"IdType":"pubmed"},"@text":"19279136"}]}},{"Citation":"Zervas M, Millet S, Ahn S, Joyner AL. Cell behaviors and genetic lineages of the mesencephalon and rhombomere 1. Neuron. 2004;43:345\u2013357.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"15294143"}]}},{"Citation":"Ellisor D, Koveal D, Hagan N, Brown A, Zervas M. Comparative analysis of conditional reporter alleles in the developing embryo and embryonic nervous system. Gene Expr Patterns. 2009;9:475\u2013489.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2855890"},{"@attributes":{"IdType":"pubmed"},"@text":"19616131"}]}},{"Citation":"Brown A, Brown S, Ellisor D, Hagan N, Normand E, et al. A practical approach to genetic inducible fate mapping: a visual guide to mark and track cells in vivo. J Vis Exp 2009","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2846818"},{"@attributes":{"IdType":"pubmed"},"@text":"20042997"}]}},{"Citation":"Feil R, Brocard J, Mascrez B, LeMeur M, Metzger D, et al. Ligand-activated site-specific recombination in mice. Proc Natl Acad Sci U S A. 1996;93:10887\u20131090.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC38252"},{"@attributes":{"IdType":"pubmed"},"@text":"8855277"}]}},{"Citation":"Joyner AL, Zervas M. Genetic inducible fate mapping in mouse: Establishing genetic lineages and defining genetic neuroanatomy in the nervous system. Dev Dyn. 2006;235:2376\u20132385.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"16871622"}]}},{"Citation":"Gross M, Dottori G, Goulding M. Lbx1 Specifies somatosensory association interneurons in the dorsal spinal cord. Neuron. 2002;34:535\u2013549.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12062038"}]}},{"Citation":"Mansouri A, Gruss P. Pax3 and Pax7 are expressed in commissural neurons and restrict ventral neuronal identity in the spinal cord. Mech Dev. 1998;78:171\u2013178.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9858722"}]}},{"Citation":"Burrill JD, Moran L, Goulding MD, Saueressig H. PAX2 is expressed in multiple spinal cord interneurons, including a population of EN1+ interneurons that require PAX6 for their development. Development. 1997;124:4493\u20134503.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9409667"}]}},{"Citation":"Pfaff S. Requirement for LIM Homeobox Gene Isl1 in Motor Neuron Generation Reveals a Motor Neuron\u2013 Dependent Step in Interneuron Differentiation. Cell. 1996;84:309\u2013320.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"8565076"}]}},{"Citation":"Cheng L. Tlx3 and Tlx1 are post-mitotic selector genes determining glutamatergic over GABAergic cell fates. Nat Neurosci. 2004;7:510\u2013518.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"15064766"}]}},{"Citation":"Avivi C. Differential expression of Islet-1 in neural crest-derived ganglia: Islet-1+dorsal root ganglion cells are post-mitotic and Islet-1+sympathetic ganglion cells are still cycling. Developmental Brain Research. 1999;115:89\u201392.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"10366706"}]}},{"Citation":"Antal M. Calcium-Binding Proteins, Parvalbumin- and Calbindin-D 28k-Immunoreactive Neurons in the Rat Spinal Cord and Dorsal Root Ganglia: A Light and Electron Microscopic Study. J Comp Neurol. 1990;295:467\u2013484.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"2351764"}]}},{"Citation":"Rottkamp CA, Lobur KJ, Wladyka CL, Lucky AK, O'Gorman S. Pbx3 is required for normal locomotion and dorsal horn development. Dev Biol. 2008;314:23\u201339.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"18155191"}]}},{"Citation":"Anderson KN, Potter AC, Piccenna LG, Quah AK, Davies KE, et al. Isolation and culture of motor neurons from the newborn mouse spinal cord. Brain Res Brain Res Protoc. 2004;12:132\u2013136.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"15013463"}]}},{"Citation":"MacDonald SC, Fleetwood IG, Hochman S, Dodd JG, Cheng GK, et al. Functional motor neurons differentiating from mouse multipotent spinal cord precursor cells in culture and after transplantation into transected sciatic nerve. J Neurosurg. 2003;98:1094\u20131103.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12744371"}]}},{"Citation":"Myers CP, Lewcock JW, Hanson MG, Gosgnach S, Aimone JB, et al. Cholinergic input is required during embryonic development to mediate proper assembly of spinal locomotor circuits. Neuron. 2005;46:37\u201349.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"15820692"}]}},{"Citation":"Muroyama Y, Fujihara M, Ikeya M, Kondoh H, Takada S. Wnt signaling plays an essential role in neuronal specification of the dorsal spinal cord. Genes Dev. 2002;16:548\u2013553.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC155351"},{"@attributes":{"IdType":"pubmed"},"@text":"11877374"}]}},{"Citation":"Li XJ, Zhang X, Johnson MA, Wang ZB, Lavaute T, et al. Coordination of sonic hedgehog and Wnt signaling determines ventral and dorsal telencephalic neuron types from human embryonic stem cells. Development. 2009;136:4055\u20134063.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2778748"},{"@attributes":{"IdType":"pubmed"},"@text":"19906872"}]}},{"Citation":"Muhr J, Andersson E, Persson M, Jessell TM, Ericson J. Groucho-mediated transcriptional repression establishes progenitor cell pattern and neuronal fate in the ventral neural tube. Cell. 2001;104:861\u2013873.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"11290324"}]}},{"Citation":"Nordstr\u00f6m U, Maier E, Jessell TM, Edlund T. An early role for WNT signaling in specifying neural patterns of Cdx and Hox gene expression and motor neuron subtype identity. PLoS Biol. 2006;4:e252.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC1502144"},{"@attributes":{"IdType":"pubmed"},"@text":"16895440"}]}},{"Citation":"Muller T. The Homeodomain Factor Lbx1 Distinguishes Two Major Programs of Neuronal Differentiation in the Dorsal Spinal Cord. Neuron. 2002;34:551\u2013562.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"12062039"}]}},{"Citation":"Erskine L, Patel K, Clarke JD. Progenitor dispersal and the origin of early neuronal phenotypes in the chick embryo spinal cord. Dev Biol. 1998;199:26\u201341.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9676190"}]}},{"Citation":"Leber SM, Sanes JR. Migratory paths of neurons and glia in the embryonic chick spinal cord. J Neurosci. 1995;15:1236\u20131248.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC6577820"},{"@attributes":{"IdType":"pubmed"},"@text":"7869095"}]}},{"Citation":"Heimbucher T, Murko C, Bajoghli B, Aghaallaei N, Huber A, et al. Gbx2 and Otx2 interact with the WD40 domain of Groucho\/Tle corepressors. Mol Cell Biol. 2007;27:340\u2013351.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC1800652"},{"@attributes":{"IdType":"pubmed"},"@text":"17060451"}]}},{"Citation":"Alvarez FJ, Jonas PC, Sapir T, Hartley R, Berrocal MC, et al. Postnatal phenotype and localization of spinal cord V1 derived interneurons. J Comp Neurol. 2005;493:177\u2013192.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2997483"},{"@attributes":{"IdType":"pubmed"},"@text":"16255029"}]}},{"Citation":"Matise MP, Joyner AL. Expression patterns of developmental control genes in normal and Engrailed-1 mutant mouse spinal cord reveal early diversity in developing interneurons. J Neurosci. 1997;17:7805\u20137816.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC6793918"},{"@attributes":{"IdType":"pubmed"},"@text":"9315901"}]}},{"Citation":"Cleary MD, Doe CQ. Regulation of neuroblast competence: multiple temporal identity factors specify distinct neuronal fates within a single early competence window. Genes Dev. 2006;20:429\u2013434.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC1369045"},{"@attributes":{"IdType":"pubmed"},"@text":"16481472"}]}},{"Citation":"Pearson BJ, Doe CQ. Regulation of neuroblast competence in Drosophila. Nature. 2003;425:624\u2013628.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"14534589"}]}},{"Citation":"Sousa VH, Miyoshi G, Hjerling-Leffler J, Karayannis T, Fishell G. Characterization of Nkx6-2-derived neocortical interneuron lineages. Cereb Cortex. 2009;19(Suppl 1):i1\u201310.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pmc"},"@text":"PMC2693535"},{"@attributes":{"IdType":"pubmed"},"@text":"19363146"}]}},{"Citation":"Soriano P. Generalized lacZ expression with the ROSA26 Cre reporter strain. Nat Genet. 1999;21:70\u20131.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"9916792"}]}},{"Citation":"Ellisor D, Zervas M. Tamoxifen dose response and conditional cell marking: Is there control? Mol Cell Neurosci. 2010;45:132\u2013138.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"20600933"}]}},{"Citation":"Robinson SP, Langan-Fahey SM, Johnson DA, Jordan VC. Metabolites, pharmacodynamics, and pharmacokinetics of tamoxifen in rats and mice compared to the breast cancer patient. Drug Metab Dispos. 1991;19:36\u201343.","ArticleIdList":{"ArticleId":[{"@attributes":{"IdType":"pubmed"},"@text":"1673419"}]}}]}]}}}