The S.ma.I2 class C Group II intron inserts at integrase related attC sites.

QUIROGA C, ROY PH, CENTRÓN D.

MICROBIOLOGY-UK

SOC GENERAL MICROBIOLOGY

Lugar: Oxford; Año: 2008 vol. 154 p. 1341 - 1353

1350-0872

We previously found the class C S.ma.I2 group II (GII) intron in Serratia marcescens SCH909 inserted into the variable region of a class 1 integron within the attC site of the ant(299)-Ia gene cassette. Here, we demonstrate that this ant(299)-Ia : : S.ma.I2 gene cassette is a recombinationally active element despite the presence of the S.ma.I2 intron. In addition, S.ma.I2 is an active GII intron capable of performing self-splicing and invading specific target sites. Intron homing to a DNA target site is RecA-independent and recognizes the intron binding site (IBS)1 and IBS3 regions, formed by the 59 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.S.ma.I2 group II (GII) intron in Serratia marcescens SCH909 inserted into the variable region of a class 1 integron within the attC site of the ant(299)-Ia gene cassette. Here, we demonstrate that this ant(299)-Ia : : S.ma.I2 gene cassette is a recombinationally active element despite the presence of the S.ma.I2 intron. In addition, S.ma.I2 is an active GII intron capable of performing self-splicing and invading specific target sites. Intron homing to a DNA target site is RecA-independent and recognizes the intron binding site (IBS)1 and IBS3 regions, formed by the 59 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.attC site of the ant(299)-Ia gene cassette. Here, we demonstrate that this ant(299)-Ia : : S.ma.I2 gene cassette is a recombinationally active element despite the presence of the S.ma.I2 intron. In addition, S.ma.I2 is an active GII intron capable of performing self-splicing and invading specific target sites. Intron homing to a DNA target site is RecA-independent and recognizes the intron binding site (IBS)1 and IBS3 regions, formed by the 59 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.ant(299)-Ia : : S.ma.I2 gene cassette is a recombinationally active element despite the presence of the S.ma.I2 intron. In addition, S.ma.I2 is an active GII intron capable of performing self-splicing and invading specific target sites. Intron homing to a DNA target site is RecA-independent and recognizes the intron binding site (IBS)1 and IBS3 regions, formed by the 59 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.S.ma.I2 intron. In addition, S.ma.I2 is an active GII intron capable of performing self-splicing and invading specific target sites. Intron homing to a DNA target site is RecA-independent and recognizes the intron binding site (IBS)1 and IBS3 regions, formed by the 59 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.9 TTGTT 39 consensus sequence located within the inverse core site of attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.attC integrons. Our results also indicate that the process for S.ma.I2 intron mobilization involves a secondary structure provided by the folding of the complete attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.attC site. Moreover, phylogenetic analysis of the class C GII introns showed a clear divergent clade formed by introns that insert within specific sites usually associated with lateral gene transfer.