Positioning the Extreme Anterior in Xenopus: Cement Gland, Primary Mouth and Anterior Pituitary. Dickinson, A., Sive, H. Seminars in Cell & Developmental Biology 18, 525-533, 2007.
Whitesnake/sfpq is required for cell survival and neuronal development in the zebrafish. Lowery, L.A., Rubin, J., Sive, H. Developmental Dynamics 236(5), 1347-1357, 2007.
Zebrafish promoter microarrays identify actively transcribed embryonic genes. Wardle, F.C., Odom, D.T., Bell, G. W., Yuan, B., Danford, T.W., Wiellette, E.L., Herbolsheimer, E., Sive, H.L., Young, R. A. and Smith, J. C. Genome Biology 7:R71, 2006 [Epub ahead of print].
The zic1 gene is
an activator of Wnt signaling. Merzdorf, C.S. and
Sive. H. International
Journal of Developmental Biology. 50, 611-617, 2006.
ZFIN Anatomy Working Group: Nervous System. Sive,
H., Mueller, T., Wullimann, M.F., Kuwada, J.Y., Moorman, S.J., Haendel,
M.A. Manually curated data, 2006.
Development of the primary mouth in Xenopus laevis.
Dickinson, A. and Sive. H. Developmental
Biology 295, 700-713, 2006.
Identification of a BMP inhibitor-responsive promoter
module required for expression of the early neural gene zic1. Tropepe,
V., Li, S., Dickinson, A., Gamse, J.T. and Sive, H.L. Developmental
Biology 289:517-529, 2006.
The zebrafish as a model for analyzing neural tube
defects. Jo, H., Lowery, L.A., Tropepe, V. and Sive, H. In Neural Tube
Defects: From Origin to Treatment (ed. D.F. Wyszynski) Oxford University
Press. pp. 29-41, 2006.
Initial formation of zebrafish brain ventricles occurs independently of circulation and requires the nagie oko and snakehead/atp1a1a.1 gene products. Lowery, L.A. and Sive, H. Development 2005 132:2057-2067.
Specification
of the enveloping layer and lack of autoneuralization in zebrafish embryonic
explants. Sagerstrom, C.G., Gammill, L.S., Veale, R. and Sive, H. Developmental
Dynamics 2005 232:85-97.
Combined haploid and insertional mutation screen in the zebrafish. Wiellette,
E., Grinblat, Y., Austen, M., Hirsinger, E., Amsterdam, A., Walker, C.,
Westerfield, M. and Sive H. Genesis
2004 40:231-240.
Identification and characterization of the posteriorly-expressed Xenopus
Neurotrophin Receptor Homolog genes fullback and fullback-like. Bromley,
E., Knapp, D., Wardle, F.C., Sun, B.I., Collins-Racie, L., LaVallie, E.,
Smith, J.C. and Sive, H. Gene
Expression Patterns 2004 5:135-140.
Strategies of vertebrate neurulation and a re-evaluation of teleost neural tube formation. Lowery, L.A. and Sive, H. Mechanisms of Development 2004 121:1189-1197.
The nlz gene family is required for hindbrain patterning in the zebrafish. Hoyle, J., Tang, Y., Wiellette, E., Wardle, F. and Sive, H. Developmental Dynamics 2004 229:835-846.
An
early requirement for fgf8 function during hindbrain pattern formation
in zebrafish. Wiellette, E.L. and Sive, H. Developmental
Dynamics 2004 229:393-399.
Can
zebrafish be used as a model to study the neurodevelopmental causes of
autism? Tropepe, V. and Sive, H.
Genes,
Brain and Behavior 2003 2:268-281.
vhnf1
and FGF signals synergize to specify rhombomere identity in the zebrafish
hindbrain. Wiellette, E.L. and Sive, H. Development
2003 130:3821-3829.
What's your position? The Xenopus cement gland
as a paradigm of regional specification. Wardle, F. and Sive, H. BioEssays
2003 25:717-726.
Direct and indirect regulation of derriere, a Xenopus
mesoderm-inducing factor, by VegT. White RJ, Sun BI, Sive HL, Smith JC.
Development
2002 129:4867-4876.
Cement gland-specific activation of the Xag1 promoter is regulated by co-operation of putative Ets and ATF/CREB transcription factors. Wardle F, Wainstock D, Sive HL. Development 2002 129:4387-4397.
zic gene expression marks anteroposterior pattern in the presumptive neurectoderm of the zebrafish gastrula. Grinblat Y, Sive HL. Developmental Dynamics 2001 Dec; 222(4):688-693.
otx2 expression in the ectoderm activates anterior neural determination and is required for Xenopus cement gland formation. Gammill L, Sive HL. Developmental Biology 2001 Dec; 240(1):223-236.
Isolation and characterization of posteriorly restricted genes in the zebrafish gastrula. Sagerstrom C, Kao B, Lane ME, Sive HL. Developmental Dynamics 2001 Apr; 220(4):402-408.
Early
anteroposterior division of the presumptive neurectoderm in Xenopus.
Gamse J, Sive HL. Mechanisms
of Development 2001 June;104(1-2):21-36.
Vertebrate anteroposterior patterning: the Xenopus
neurectoderm as a paradigm. Gamse J, Sive HL. BioEssays
2000 22:976-986.
Different activities of the Frizzled related proteins frzb2 and sizzled2 during Xenopus anteroposterior patterning. Bradley L, Sun B, Collins-Racie LA, LaVallie ER, DiBlasio-Smith EA, McCoy JM, Sive HL. Developmental Biology 2000 Nov;227(1):118-132.
Coincidence
of otx2 and BMP4 signaling during Xenopus cement gland formation.
Gammill L, Sive HL. Mechanisms
of Development 2000 Apr;92(2):217-226.
Early development of Xenopus
laevis: a laboratory manual. Sive HL, Grainger R, Harlard R. Cold
Spring Harbor Laboratory Press, 2000.
derriere: a TGF-beta family member required for posterior development in Xenopus. Sun BI, Bush SM, Collins-Racie LA, LaVallie ER, DiBlasio-Smith EA, Wolfman NM, McCoy JM, Sive HL. Development 1999 Apr;126(7):1467-82
Determination of the zebrafish forebrain: induction and patterning. Grinblat Y, Gamse J, Patel M, Sive HL. Development 1998 Nov;125(22):4403-16.
opl:
a zinc finger protein that regulates neural determination and patterning
in Xenopus. Kuo JS, Patel M, Gamse J, Merzdorf C, Liu X, Apekin
V, Sive HL. Development.
1998 Aug; 125(15): 2867-2882.
Analysis
of zebrafish development using explant culture assays. Grinblat Y, Lane
ME, Sagerstrom CG, Sive HL. In
The Zebrafish: Methods in Cell Biology, vol. 59 (ed. H.W. Dietrich,
M. Westerfield and L. Zon) San Diego, Academic Press, 1998 pp 127-159.
Subtractive
cloning: past, present, and future. Sagerstrom CG, Sun BI, Sive HL. Annual
Review of Biochemistry 1997;66:751-783.
Retinoids
and posterior neural induction: a reevaluation of Nieuwkoop's two-step
hypothesis. Kolm PJ, Sive HL. Cold
Spring Harb Symp Quant Biol 1997;62:511-521.
Xenopus hindbrain patterning requires retinoid signaling. Kolm PJ, Apekin V, Sive HL. Developmental Biology 1997 Dec 1;192(1):1-16
Identification of otx2 target genes and restrictions in ectodermal competence during Xenopus cement gland formation. Gammill LS, Sive H. Development 1997 Jan;124(2):471-481
Translational inhibition by 5'-polycytidine tracts in Xenopus embryos and in vitro. Kuo JS, Veale R, Maxwell B, Sive H. Gene 1996 Oct 17;176(1-2):17-21
Positive and negative signals modulate formation of the Xenopus cement gland. Bradley L, Wainstock D, Sive H. Development 1996 Sep;122(9):2739-2750
Anteroposterior
patterning in the zebrafish, Danio rerio: an explant assay reveals
inductive and suppressive cell interactions. Sagerstrom CG, Grinbalt Y,
Sive H. Development
1996 Jun;122(6):1873-1883
A sticky problem: the Xenopus cement gland as a paradigm for anteroposterior
patterning. Sive H, Bradley L. Developmental
Dynamics 1996 Mar;205(3):265-280.
Subtractive cDNA cloning. Patel M, Sive HL. Protocols in Molecular Biology.
1996 Unit 5.11.
Efficient hormone-inducible protein function in Xenopus laevis. Kolm PJ, Sive HL. Developmental Biology 1995 Sep;171(1):267-272
Regulation of the Xenopus labial homeodomain genes, HoxA1 and HoxD1: activation by retinoids and peptide growth factors. Kolm PJ, Sive HL. Dev Biol 1995 Jan;167(1):34-49
Complex regulation of Xenopus HoxAI and HoxDI. Kolm PJ, Sive HL. Biochem Soc Trans 1994 Aug;22(3):579-584
The frog prince-ss: a molecular formula for dorsoventral patterning in Xenopus. Sive HL. Genes Dev 1993 Jan;7(1):1-12
