Viewing entries tagged
olfactory epithelium

Tg(-8.0cldnb:lynGFP)zf106

Tg(-8.0cldnb:lynGFP)zf106

About

construct:
Tg(-8.0cldnb:LY-EGFP)

This transgenic line was created by the Gilmore lab “ Eight kilobases of sequence directly upstream of the Claudin B start codon were amplified from BAC zK241F11 by using the Expand Long Template PCR System (Roche). The resultant fragment was cloned into a vector containing lynEGFPpA (Koster and Fraser, 2001) flanked by sites for I-SceI, and the resultant construct was injected into one-cell zebrafish embryos by following the meganuclease transgenesis protocol (Thermes et al., 2002).”(Haas & Gilmore, 2006).

The Gilmore lab wanted to label the lateral line and neuromasts of the lateral line system, one allele of this transgenic also had EGFP expression in the nasal retina and telencephalon and has been used by other labs to study eye and telencephalic morphogenesis.

External Links:

 ZFIN

Lab or Origin: Gilmore Lab

Expressed in: 

neuromasts, lateral line, olfactory epithelium, olfactory bulb, , pallium, subpallium, tract of the habenula commissure, nasal retina.

 

Key Publications

 Haas, P., and Gilmour, D. (2006)
Chemokine signaling mediates self-organizing tissue migration in the zebrafish lateral line.
Developmental Cell. 10(5):673-680.

Folgueira, M., Bayley, P., Navratilova, P., Becker, T.S., Wilson, S.W., and Clarke, J.D. (2012)
Morphogenesis underlying the development of the everted teleost telencephalon.
Neural Development. 7(1):32.

Valdivia, L.E., Young, R.M., Hawkins, T.A., Stickney, H.L., Cavodeassi, F., Schwarz, Q., Pullin, L.M., Villegas, R., Moro, E., Argenton, F., Allende, M.L., and Wilson, S.W. (2011)
Lef1-dependent Wnt/β-catenin signalling drives the proliferative engine that maintains tissue homeostasis during lateral line development.
Development (Cambridge, England). 138(18):3931-3941.

Valentin, G., Haas, P., and Gilmour, D. (2007)
The chemokine SDF1a coordinates tissue migration through the spatially restricted activation of Cxcr7 and Cxcr4b.
Current biology : CB. 17(12):1026-1031.

Picker, A., Cavodeassi, F., Machate, A., Bernauer, S., Hans, S., Abe, G., Kawakami, K., Wilson, S.W., and Brand, M. (2009)
Dynamic coupling of pattern formation and morphogenesis in the developing vertebrate retina.
PLoS Biology. 7(10):e1000214.



Tg(slc17a6b: DsRed)nns9Tg

Tg(slc17a6b: DsRed)nns9Tg

About

 Slc17a6b is a vesicular glutamate transporter that that mediates the uptake of the excitatory neurotransmitter glutamate into vesicles in the presynaptic terminals of excitatory neurons. This BAC transgenic line from the Yoshihara lab drives the expression of DSRed in glutamatergic neurons. Expression can be seen in many neurons throughout the brain. Strong expression in the dorsal and ventral habenular subnuclei, olfactory bulbs, the pallium and optic tectum

External Links:

 ZFIN

Lab or Origin: Yoshihara Lab

Expressed in: 

 glutamatergic neurons, olfactory epithelium, olfactory bulb, pallium, subpallium, dorsal habenula, ventral habenula, preoptic area, prethalamus, pretectum (AF9), optic tectum, trigeminal sensory ganglion.

Key Publications

 
Miyasaka, N., Morimoto, K., Tsubokawa, T., Higashijima, S., Okamoto, H., and Yoshihara, Y. (2009)
From the olfactory bulb to higher brain centers: genetic visualization of secondary olfactory pathways in zebrafish.
The Journal of neuroscience. 29(15):4756-4767.

Kani, S., Bae, Y.K., Shimizu, T., Tanabe, K., Satou, C., Parsons, M.J., Scott, E., Higashijima, S.I., and Hibi, M. (2010) Proneural gene-linked neurogenesis in zebrafish cerebellum.
Developmental Biology. 343(1-2):1-17.