scholarly journals Identification of a family of group II introns encoding LAGLIDADG ORFs typical of group I introns

RNA ◽  
2002 ◽  
Vol 8 (11) ◽  
pp. 1373-1377 ◽  
Author(s):  
NAVTEJ TOOR ◽  
STEVEN ZIMMERLY
Keyword(s):  
Group I Introns ◽  
Group Ii Introns ◽  
Group I ◽  
Group Ii

scholarly journals Organellar Introns in Fungi, Algae, and Plants

Cells ◽  
2021 ◽  
Vol 10 (8) ◽  
pp. 2001
Author(s):  
Jigeesha Mukhopadhyay ◽  
Georg Hausner
Keyword(s):  
Gene Expression ◽  
Ribosomal Proteins ◽  
Heterologous Gene Expression ◽  
Group I Introns ◽  
Group Ii Introns ◽  
Homing Endonucleases ◽  
Organellar Genomes ◽  
Chloroplast Genomes ◽  
Group I ◽  
Group Ii

Introns are ubiquitous in eukaryotic genomes and have long been considered as ‘junk RNA’ but the huge energy expenditure in their transcription, removal, and degradation indicate that they may have functional significance and can offer evolutionary advantages. In fungi, plants and algae introns make a significant contribution to the size of the organellar genomes. Organellar introns are classified as catalytic self-splicing introns that can be categorized as either Group I or Group II introns. There are some biases, with Group I introns being more frequently encountered in fungal mitochondrial genomes, whereas among plants Group II introns dominate within the mitochondrial and chloroplast genomes. Organellar introns can encode a variety of proteins, such as maturases, homing endonucleases, reverse transcriptases, and, in some cases, ribosomal proteins, along with other novel open reading frames. Although organellar introns are viewed to be ribozymes, they do interact with various intron- or nuclear genome-encoded protein factors that assist in the intron RNA to fold into competent splicing structures, or facilitate the turn-over of intron RNAs to prevent reverse splicing. Organellar introns are also known to be involved in non-canonical splicing, such as backsplicing and trans-splicing which can result in novel splicing products or, in some instances, compensate for the fragmentation of genes by recombination events. In organellar genomes, Group I and II introns may exist in nested intronic arrangements, such as introns within introns, referred to as twintrons, where splicing of the external intron may be dependent on splicing of the internal intron. These nested or complex introns, with two or three-component intron modules, are being explored as platforms for alternative splicing and their possible function as molecular switches for modulating gene expression which could be potentially applied towards heterologous gene expression. This review explores recent findings on organellar Group I and II introns, focusing on splicing and mobility mechanisms aided by associated intron/nuclear encoded proteins and their potential roles in organellar gene expression and cross talk between nuclear and organellar genomes. Potential application for these types of elements in biotechnology are also discussed.

Detection of group I and group II introns in a Mexican Bacillus thuringiensis collection

2010 ◽  
Author(s):  
A. Espino-Vázquez ◽  
A. Solís-Soto ◽  
H.A. Luna-Olvera ◽  
H. Medrano-Roldán ◽  
B. Pereyra-Alférez
Keyword(s):  
Bacillus Thuringiensis ◽  
Group Ii Introns ◽  
Group I ◽  
Group Ii

Group I and group II introns.

1993 ◽  
Vol 7 (1) ◽  
pp. 15-24 ◽  
Author(s):  
R Saldanha ◽  
G Mohr ◽  
M Belfort ◽  
A M Lambowitz
Keyword(s):  
Group Ii Introns ◽  
Group I ◽  
Group Ii

scholarly journals Multiple Homing Pathways Used by Yeast Mitochondrial Group II Introns

2000 ◽  
Vol 20 (22) ◽  
pp. 8432-8446 ◽  
Author(s):  
Robert Eskes ◽  
Lu Liu ◽  
Hongwen Ma ◽  
Michael Y. Chao ◽  
Lorna Dickson ◽  
...  
Keyword(s):  
Repair Process ◽  
Strand Break ◽  
Target Site ◽  
Host Cells ◽  
Antisense Strand ◽  
Group Ii Introns ◽  
Recombination Mechanism ◽  
Group I ◽  
Sense Strand ◽  
Group Ii

ABSTRACT The yeast mitochondrial DNA group II introns aI1 and aI2 are retroelements that insert site specifically into intronless alleles by a process called homing. Here, we used patterns of flanking marker coconversion in crosses with wild-type and mutant aI2 introns to distinguish three coexisting homing pathways: two that were reverse transcriptase (RT) dependent (retrohoming) and one that was RT independent. All three pathways are initiated by cleavage of the recipient DNA target site by the intron-encoded endonuclease, with the sense strand cleaved by partial or complete reverse splicing, and the antisense strand cleaved by the intron-encoded protein. The major retrohoming pathway in standard crosses leads to insertion of the intron with unidirectional coconversion of upstream exon sequences. This pattern of coconversion suggests that the major retrohoming pathway is initiated by target DNA-primed reverse transcription of the reverse-spliced intron RNA and completed by double-strand break repair (DSBR) recombination with the donor allele. The RT-independent pathway leads to insertion of the intron with bidirectional coconversion and presumably occurs by a conventional DSBR recombination mechanism initiated by cleavage of the recipient DNA target site by the intron-encoded endonuclease, as for group I intron homing. Finally, some mutant DNA target sites shift up to 43% of retrohoming to another pathway not previously detected for aI2 in which there is no coconversion of flanking exon sequences. This new pathway presumably involves synthesis of a full-length cDNA copy of the inserted intron RNA, with completion by a repair process independent of homologous recombination, as found for the Lactococcus lactis Ll.LtrB intron. Our results show that group II intron mobility can occur by multiple pathways, the ratios of which depend on the characteristics of both the intron and the DNA target site. This remarkable flexibility enables group II introns to use different recombination and repair enzymes in different host cells.

scholarly journals The splicing of yeast mitochondrial group I and group II introns requires a DEAD-box protein with RNA chaperone function

2004 ◽  
Vol 102 (1) ◽  
pp. 163-168 ◽  
Author(s):  
H.-R. Huang ◽  
C. E. Rowe ◽  
S. Mohr ◽  
Y. Jiang ◽  
A. M. Lambowitz ◽  
...  
Keyword(s):  
Group Ii Introns ◽  
Rna Chaperone ◽  
Chaperone Function ◽  
Dead Box ◽  
Group I ◽  
Group Ii

scholarly journals Chloroplast Genomes of the Green-Tide Forming Alga Ulva compressa: Comparative Chloroplast Genomics in the Genus Ulva (Ulvophyceae, Chlorophyta)

2021 ◽  
Vol 8 ◽  
Author(s):  
Feng Liu ◽  
James T. Melton
Keyword(s):  
Homing Endonuclease ◽  
Intergenic Spacer ◽  
Green Tide ◽  
Group I Introns ◽  
Intron Insertion ◽  
Chloroplast Genomes ◽  
Group I ◽  
Ulva Compressa ◽  
Insertion Sites ◽  
Group Ii

To understand the evolution of Ulva chloroplast genomes at intraspecific and interspecific levels, in this study, three complete chloroplast genomes of Ulva compressa Linnaeus were sequenced and compared with the available Ulva cpDNA data. Our comparative analyses unveiled many noticeable findings. First, genome size variations of Ulva cpDNAs at intraspecific and interspecific levels were mainly caused by differences in gain or loss of group I/II introns, integration of foreign DNA fragments, and content of non-coding intergenic spacer regions. Second, chloroplast genomes of U. compressa shared the same 100 conserved genes as other Ulva cpDNA, whereas Ulva flexuosa appears to be the only Ulva species with the minD gene retained in its cpDNA. Third, five types of group I introns, most of which carry a LAGLIDADG or GIY-YIG homing endonuclease, and three of group II introns, usually encoding a reverse transcriptase/maturase, were detected at 26 insertion sites of 14 host genes in the 23 Ulva chloroplast genomes, and many intron insertion-sites have been found for the first time in Chlorophyta. Fourth, one degenerate group II intron previously ignored has been detected in the infA genes of all Ulva species, but not in the closest neighbor, Pseudoneochloris marina, and the other chlorophycean taxa, indicating that it should be the result of an independent invasion event that occurred in a common ancestor of Ulva species. Finally, the seven U. compressa cpDNAs represented a novel gene order which was different from that of other Ulva cpDNAs. The structure of Ulva chloroplast genomes is not conserved, but remarkably plastic, due to multiple rearrangement events.

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