Cell division in the fission yeast Schizosaccharomyces pombe yields two equal-sized daughter cells. Medial fission is achieved by deposition of a primary septum flanked by two secondary septa within the dividing cell. During the final step of cell division, cell separation, the primary septum is hydrolyzed by an endo-(1,3)--glucanase, Eng1p. We reasoned that the cell wall material surrounding the septum, referred to here as the septum edging, also must be hydrolyzed before full separation of the daughter cells can occur. Because the septum edging contains (1,3)-␣-glucan, we investigated the cellular functions of the putative (1,3)-␣-glucanases Agn1p and Agn2p. Whereas agn2 deletion results in a defect in endolysis of the ascus wall, deletion of agn1 leads to clumped cells that remained attached to each other by septum-edging material. Purified Agn1p hydrolyzes (1,3)-␣-glucan predominantly into pentasaccharides, indicating an endo-catalytic mode of hydrolysis. Furthermore, we show that the transcription factors Sep1p and Ace2p regulate both eng1 and agn1 expression in a cell cycle-dependent manner. We propose that Agn1p acts in concert with Eng1p to achieve efficient cell separation, thereby exposing the secondary septa as the new ends of the daughter cells.
In mitochondria of Kinetoplastida belonging to the suborder Trypanosomatina, the nucleotide sequence of transcripts is post‐transcriptionally edited via insertion and deletion of uridylate residues. In order to shed more light on the evolutionary history of this process we have searched for editing in mitochondrial RNAs of Trypanoplasma borreli, an organism belonging to the suborder Bodonina. We have cloned and sequenced a 5.3 kb fragment derived from a 37 kb mitochondrial DNA molecule which does not appear to be a part of a network structure and have found genes encoding cytochrome c oxidase (cox) subunit 1, cox 2 and apocytochrome (cyt) b, and genes encoding the small and large subunit mitoribosomal RNAs. The order in which these genes occur is completely different from that of trypanosomatid maxicircle genes. The 5′ and 3′ termini of both the cytb and cox1 gene are cryptic, the protein coding sequences being created by extensive insertion/deletion of Us in the corresponding mRNA sections. Phylogenetic analyses of the protein and ribosomal RNA sequences demonstrated that the separation between T.borreli and Trypanosomatina was an early event, implying that U‐insertion/deletion processes are ancient. Different patterns of editing have persisted in different lineages, however, since editing of cox1 RNA and of relatively small 3′‐terminal RNA sections is not found in trypanosomatids. In contrast, cox2 RNA which is edited in trypanosomatids by the insertion of four Us, is unedited in T.borreli.
The Escherichia coli DNA repair enzyme AlkB is a 2-oxoglutarate (2OG)-dependent Fe(2+) binding dioxygenase that removes methyl lesions from DNA and RNA. To date, nine human AlkB homologues are known: ABH1 to ABH8 and the obesity-related FTO. Similar to AlkB, these homologues exert their activity on nucleic acids, although for some homologues the biological substrate remains to be identified. 2OG dioxygenases require binding of the cofactors Fe(2+) and 2OG in the active site to form a catalytically competent complex. We present a structural analysis of AlkB using NMR, fluorescence, and CD spectroscopy to show that AlkB is a dynamic protein exhibiting different folding states. In the absence of the cofactors Fe(2+) and 2OG, apoAlkB is a highly dynamic protein. Binding of either Fe(2+) or 2OG alone does not significantly affect the protein dynamics. Formation of a fully folded and catalytically competent holoAlkB complex only occurs when both 2OG and Fe(2+) are bound. These findings provide the first insights into protein folding of 2OG-dependent dioxygenases. A role for protein dynamics in the incorporation of the metal cofactor is discussed.
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