Structural basis for recognition of intron branchpoint RNA by yeast Msl5 and selective effects of interfacial mutations on splicing of yeast pre-mRNAs

2016

RNA

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Luc7 is an essential 261-amino acid protein subunit of the Saccharomyces cerevisiae U1 snRNP. To establish structure-function relations for yeast Luc7, we conducted an in vivo mutational analysis entailing N-and C-terminal truncations and alanine scanning of phylogenetically conserved amino acids, including two putative zinc finger motifs, ZnF1 and ZnF2, and charged amino acids within the ZnF2 module. We identify Luc7-(31-246) as a minimal functional protein and demonstrate that whereas mutations of the CCHH ZnF2 motif are lethal, mutations of the ZnF1 CCCH motif and the charged residues of the ZnF2 modules are not. Though dispensable for vegetative growth in an otherwise wild-type background, the N-terminal 18-amino acid segment of Luc7 plays an important role in U1 snRNP function, evinced by our findings that its deletion (i) impaired the splicing of SUS1 pre-mRNA; (ii) was synthetically lethal absent other U1 snRNP constituents (Mud1, Nam8, the TMG cap, the C terminus of Snp1), absent the Mud2 subunit of the Msl5•Mud2 branchpoint binding complex, and when the m 7 G cap-binding site of Cbc2 was debilitated; and (iii) bypassed the need for the essential DEAD-box ATPase Prp28. Similar phenotypes were noted for ZnF1 mutations C45A, C53A, and C68A and ZnF2 domain mutations D214A, R215A, R216A, and D219A. These findings highlight the contributions of the Luc7 N-terminal peptide, the ZnF1 motif, and the ZnF2 module in stabilizing the interactions of the U1 snRNP with the pre-mRNA 5 ′ splice site and promoting the splicing of a yeast pre-mRNA, SUS1, that has a nonconsensus 5 ′ splice site.

Section: Luc7 Mutations Bypass the Essentiality Of Prp28supporting

confidence: 86%

Section: Luc7 Mutations Bypass the Essentiality Of Prp28mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Structure–function analysis and genetic interactions of the Luc7 subunit of the Saccharomyces cerevisiae U1 snRNP

Agarwal

2016

RNA

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“…Genetic analyses in yeast have revealed an extensive network of buffered functions during spliceosome assembly, defined by the numerous instances in which null alleles of vegetatively inessential splicing factors, or benign mutations in essential players, elicit synthetic lethal and sick phenotypes when combined with other benign mutations in the splicing machinery (Liao et al 1991;Abovich et al 1994;Colot et al 1996;Gottschalk et al 1998;Hausmann et al 2008;Wilmes et al 2008;Costanzo et al 2010;Chang et al 2012;Qiu et al 2012;Schwer et al 2013;Shuman 2014, 2015;Jacewicz et al 2015;Agarwal et al 2016). The present collection of biologically active mutants targeted to conserved SmG, SmE, and SmF amino acids at their RNA binding sites or subunit interfaces enables us to survey genetic interactions of these three Sm ring subunits.…”

Section: Genetic Interactions Of Sm Mutants With Non-sm Splicing Factorsmentioning

confidence: 99%

Structure–function analysis and genetic interactions of the SmG, SmE, and SmF subunits of the yeast Sm protein ring

Kruchten

2016

RNA

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A seven-subunit Sm protein ring forms a core scaffold of the U1, U2, U4, and U5 snRNPs that direct pre-mRNA splicing. Using human snRNP structures to guide mutagenesis in Saccharomyces cerevisiae, we gained new insights into structure-function relationships of the SmG, SmE, and SmF subunits. An alanine scan of 19 conserved amino acids of these three proteins, comprising the Sm RNA binding sites or inter-subunit interfaces, revealed that, with the exception of Arg74 in SmF, none are essential for yeast growth. Yet, for SmG, SmE, and SmF, as for many components of the yeast spliceosome, the effects of perturbing protein-RNA and protein-protein interactions are masked by built-in functional redundancies of the splicing machine. For example, tests for genetic interactions with non-Sm splicing factors showed that many benign mutations of SmG, SmE, and SmF (and of SmB and SmD3) were synthetically lethal with null alleles of U2 snRNP subunits Lea1 and Msl1. Tests of pairwise combinations of SmG, SmE, SmF, SmB, and SmD3 alleles highlighted the inherent redundancies within the Sm ring, whereby simultaneous mutations of the RNA binding sites of any two of the Sm subunits are lethal. Our results suggest that six intact RNA binding sites in the Sm ring suffice for function but five sites may not.

“…When structures are available, they can be exploited to program mutations with specific functional defects and then systematically test an allelic series for phenotypes per se and for synthetic genetic interactions with other spliceosome components or splicing factors. Toward this end, we have solved crystal structures of the yeast Msl5 • branchpoint RNA complex and the yeast Prp28•AMPPNP complex and have subjected these proteins to structure-guided mutagenesis (Jacewicz et al 2014(Jacewicz et al , 2015. However, there is (to our knowledge) no structure in hand for any component of the yeast U1 snRNP.…”

Section: Introductionmentioning

confidence: 99%

Structure–function analysis and genetic interactions of the Yhc1, SmD3, SmB, and Snp1 subunits of yeast U1 snRNP and genetic interactions of SmD3 with U2 snRNP subunit Lea1

2015

RNA

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Yhc1 and U1-C are essential subunits of the yeast and human U1 snRNP, respectively, that stabilize the duplex formed by U1 snRNA at the pre-mRNA 5 ′ splice site (5 ′ SS). Mutational analysis of Yhc1, guided by the human U1 snRNP crystal structure, highlighted the importance of Val20 and Ser19 at the RNA interface. Though benign on its own, V20A was lethal in the absence of branchpoint-binding complex subunit Mud2 and caused a severe growth defect in the absence of U1 subunit Nam8. S19A caused a severe defect with mud2△. Essential DEAD-box ATPase Prp28 was bypassed by mutations of Yhc1 Val20 and Ser19, consistent with destabilization of U1•5 ′ SS interaction. We extended the genetic analysis to SmD3, which interacts with U1-C/Yhc1 in U1 snRNP, and to SmB, its neighbor in the Sm ring. Whereas mutations of the interface of SmD3, SmB, and U1-C/Yhc1 with U1-70K/Snp1, or deletion of the interacting Snp1 N-terminal peptide, had no growth effect, they elicited synthetic defects in the absence of U1 subunit Mud1. Mutagenesis of the RNA-binding triad of SmD3 (Ser-Asn-Arg) and SmB (His-Asn-Arg) provided insights to built-in redundancies of the Sm ring, whereby no individual side-chain was essential, but simultaneous mutations of Asn or Arg residues in SmD3 and SmB were lethal. Asn-to-Ala mutations SmB and SmD3 caused synthetic defects in the absence of Mud1 or Mud2. All three RNA site mutations of SmD3 were lethal in cells lacking the U2 snRNP subunit Lea1. Benign C-terminal truncations of SmD3 were dead in the absence of Mud2 or Lea1 and barely viable in the absence of Nam8 or Mud1. In contrast, SMD3-E35A uniquely suppressed the temperature-sensitivity of lea1△.