Kaushik Saha scite author profile

Recognition of highly degenerate mammalian splice sites by the core spliceosomal machinery is regulated by several protein factors that predominantly bind exonic splicing motifs. These are postulated to be single-stranded in order to be functional, yet knowledge of secondary structural features that regulate the exposure of exonic splicing motifs across the transcriptome is not currently available. Using transcriptome-wide RNA structural information we show that retained introns in mouse are commonly flanked by a short (≲70 nucleotide), highly base-paired segment upstream and a predominantly single-stranded exonic segment downstream. Splicing assays with select pre-mRNA substrates demonstrate that loops immediately upstream of the introns contain pre-mRNA-specific splicing enhancers, the substitution or hybridization of which impedes splicing. Additionally, the exonic segments flanking the retained introns appeared to be more enriched in a previously identified set of hexameric exonic splicing enhancer (ESE) sequences compared to their spliced counterparts, suggesting that base-pairing in the exonic segments upstream of retained introns could be a means for occlusion of ESEs. The upstream exonic loops of the test substrate promoted recruitment of splicing factors and consequent pre-mRNA structural remodeling, leading up to assembly of the early spliceosome. These results suggest that disruption of exonic stem–loop structures immediately upstream (but not downstream) of the introns regulate alternative splicing events, likely through modulating accessibility of splicing factors.

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Discovery of a pre-mRNA structural scaffold as a contributor to the mammalian splicing code

Saha

Fernandez

Biswas

et al. 2018

Preprint

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For splicing of a metazoan pre-mRNA, the four major splice signals -5′ and 3′ splice sites (SS), branch-point site (BS), and a poly-pyrimidine tract (PPT) -are initially bound by splicing factors U1 snRNP, U2AF35, SF1, and U2AF65, respectively, leading up to an early spliceosomal complex, the E-complex. The E-complex consists of additional components and the mechanism of its assembly is unclear. Hence, how splice signals are organized within E-complex defining the exon-intron boundaries remains elusive. Here we present in vitro stepwise reconstitution of an early spliceosome, assembled by cooperative actions of U1 snRNP, SRSF1, SF1, U2AF65, U2AF35, and hnRNP A1, termed here the recognition (R) complex, within which both splice sites are recognized. The R-complex assembly indicates that the SRSF1:pre-mRNA complex initially defines a substrate for U1 snRNP, engaging exons at both ends of an intron. Subsequent 5′SSdependent U1 snRNP binding enables recognition of the remaining splice signals, defining the intron. This R-complex assembly indicates the minimal constituents for intron definition revealing mechanistic principles behind the splice site recognition.

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Characterization of the evolutionarily conserved iron–sulfur cluster of sirohydrochlorin ferrochelatase from Arabidopsis thaliana

Saha

Webb

Rigby

et al. 2012

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Sirohaem is a cofactor of nitrite and sulfite reductases, essential for assimilation of nitrogen and sulfur. Sirohaem is synthesized from the central tetrapyrrole intermediate uroporphyrinogen III by methylation, oxidation and ferrochelation reactions. In Arabidopsis thaliana, the ferrochelation step is catalysed by sirohydrochlorin ferrochelatase (SirB), which, unlike its counterparts in bacteria, contains an [Fe-S] cluster. We determined the cluster to be a [4Fe-4S] type, which quickly oxidizes to a [2Fe-2S] form in the presence of oxygen. We also identified the cluster ligands as four conserved cysteine residues located at the C-terminus. A fifth conserved cysteine residue, Cys(135), is not involved in ligating the cluster directly, but influences the oxygen-sensitivity of the [4Fe-4S] form, and possibly the affinity for the substrate metal. Substitution mutants of the enzyme lacking the Fe-S cluster or Cys(135) retain the same specific activity in vitro and dimeric quaternary structure as the wild-type enzyme. The mutant variants also rescue a defined Escherichia coli sirohaem-deficient mutant. However, the mutant enzymes cannot complement Arabidopsis plants with a null AtSirB mutation, which exhibits post-germination arrest. These observations suggest an important physiological role for the Fe-S cluster in Planta, highlighting the close association of iron, sulfur and tetrapyrrole metabolism.

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Identification and characterization of theArabidopsisgene encoding the tetrapyrrole biosynthesis enzyme uroporphyrinogen III synthase

Tan

Cheng

Saha

et al. 2008

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UROS (uroporphyrinogen III synthase; EC 4.2.1.75) is the enzyme responsible for the formation of uroporphyrinogen III, the precursor of all cellular tetrapyrroles including haem, chlorophyll and bilins. Although UROS genes have been cloned from many organisms, the level of sequence conservation between them is low, making sequence similarity searches difficult. As an alternative approach to identify the UROS gene from plants, we used functional complementation, since this does not require conservation of primary sequence. A mutant of Saccharomyces cerevisiae was constructed in which the HEM4 gene encoding UROS was deleted. This mutant was transformed with an Arabidopsis thaliana cDNA library in a yeast expression vector and two colonies were obtained that could grow in the absence of haem. The rescuing plasmids encoded an ORF (open reading frame) of 321 amino acids which, when subcloned into an Escherichia coli expression vector, was able to complement an E. coli hemD mutant defective in UROS. Final proof that the ORF encoded UROS came from the fact that the recombinant protein expressed with an N-terminal histidine-tag was found to have UROS activity. Comparison of the sequence of AtUROS (A. thaliana UROS) with the human enzyme found that the seven invariant residues previously identified were conserved, including three shown to be important for enzyme activity. Furthermore, a structure-based homology search of the protein database with AtUROS identified the human crystal structure. AtUROS has an N-terminal extension compared with orthologues from other organisms, suggesting that this might act as a targeting sequence. The precursor protein of 34 kDa translated in vitro was imported into isolated chloroplasts and processed to the mature size of 29 kDa. Confocal microscopy of plant cells transiently expressing a fusion protein of AtUROS with GFP (green fluorescent protein) confirmed that AtUROS was targeted exclusively to chloroplasts in vivo.

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Cooperative engagement and subsequent selective displacement of SR proteins define the pre-mRNA 3D structural scaffold for early spliceosome assembly

Saha

Ghosh

2022

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We recently reported that serine–arginine-rich (SR) protein-mediated pre-mRNA structural remodeling generates a pre-mRNA 3D structural scaffold that is stably recognized by the early spliceosomal components. However, the intermediate steps between the free pre-mRNA and the assembled early spliceosome are not yet characterized. By probing the early spliceosomal complexes in vitro and RNA-protein interactions in vivo, we show that the SR proteins bind the pre-mRNAs cooperatively generating a substrate that recruits U1 snRNP and U2AF65 in a splice signal-independent manner. Excess U1 snRNP selectively displaces some of the SR protein molecules from the pre-mRNA generating the substrate for splice signal-specific, sequential recognition by U1 snRNP, U2AF65 and U2AF35. Our work thus identifies a novel function of U1 snRNP in mammalian splicing substrate definition, explains the need for excess U1 snRNP compared to other U snRNPs in vivo, demonstrates how excess SR proteins could inhibit splicing, and provides a conceptual basis to examine if this mechanism of splicing substrate definition is employed by other splicing regulatory proteins.

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Kaushik Saha

Structural disruption of exonic stem–loops immediately upstream of the intron regulates mammalian splicing

Discovery of a pre-mRNA structural scaffold as a contributor to the mammalian splicing code

Characterization of the evolutionarily conserved iron–sulfur cluster of sirohydrochlorin ferrochelatase from Arabidopsis thaliana

Identification and characterization of theArabidopsisgene encoding the tetrapyrrole biosynthesis enzyme uroporphyrinogen III synthase

Cooperative engagement and subsequent selective displacement of SR proteins define the pre-mRNA 3D structural scaffold for early spliceosome assembly

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