TY - JOUR
T1 - Construction of marker-free transplastomic plants
AU - Lutz, Kerry A.
AU - Maliga, Pal
N1 - Funding Information:
Original research reported from the Maliga laboratory was supported by the National Science Foundation Eukaryotic Genetics Program award MCB-0319958 and the USDA Biotechnology Risk Assessment Research Grant Program award 2005-33120-16524. Kerry A Lutz is the recipient of a Charles and Johanna Busch Predoctoral Fellowship.
PY - 2007/4
Y1 - 2007/4
N2 - Because of its prokaryotic-type gene expression machinery, maternal inheritance and the opportunity to express proteins at a high level, the plastid genome (plastome or ptDNA) is an increasingly popular target for engineering. The ptDNA is present as up to 10 000 copies per cell, making selection for marker genes essential to obtain plants with uniformly transformed ptDNA. However, the marker gene is no longer desirable when homoplastomic plants are obtained. Marker-free transplastomic plants can now be obtained with four recently developed protocols: homology-based excision via directly repeated sequences, excision by phage site-specific recombinanses, transient cointegration of the marker gene, and the cotransformation-segregation approach. Marker excision technology will benefit applications in agriculture and in molecular farming.
AB - Because of its prokaryotic-type gene expression machinery, maternal inheritance and the opportunity to express proteins at a high level, the plastid genome (plastome or ptDNA) is an increasingly popular target for engineering. The ptDNA is present as up to 10 000 copies per cell, making selection for marker genes essential to obtain plants with uniformly transformed ptDNA. However, the marker gene is no longer desirable when homoplastomic plants are obtained. Marker-free transplastomic plants can now be obtained with four recently developed protocols: homology-based excision via directly repeated sequences, excision by phage site-specific recombinanses, transient cointegration of the marker gene, and the cotransformation-segregation approach. Marker excision technology will benefit applications in agriculture and in molecular farming.
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U2 - 10.1016/j.copbio.2007.02.003
DO - 10.1016/j.copbio.2007.02.003
M3 - Review article
C2 - 17339108
AN - SCOPUS:34147139529
SN - 0958-1669
VL - 18
SP - 107
EP - 114
JO - Current Opinion in Biotechnology
JF - Current Opinion in Biotechnology
IS - 2
ER -