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ABSTRACT Pre-mRNA splicing is an essential step in eukaryotic gene expression during which spliceosomes remove introns from nascent RNAs while ligating the adjacent exons. Spliceosomes are cellular nanomachines composed of five small nuclear (snRNA) components and dozens of proteins, most of which are highly conserved. Despite the high conservation of many splicing factors between S. cerevisiae and H. sapiens , several protein components of the S. cerevisiae spliceosome are not essential for growth under normal laboratory conditions. This is particularly surprising for nonessential factors whose conserved domains contact the spliceosome’s catalytic core. Uncovering a function for these splicing factors can be challenging since they are not required for viability, may engage in functionally redundant interactions, and may display only weak phenotypes in the absence of secondary mutations in other spliceosome components. One such nonessential factor is the Cwc15 protein. Cwc15’s highly conserved N-terminus directly contacts the U2/U6 di-snRNA within the spliceosome catalytic core; yet its precise role in splicing has not been defined in any organism. In this work, we use molecular genetics in S. cerevisiae combined with splicing reporter assays to study Cwc15p function. We propose that Cwc15p not only promotes active site stability during 5’ splice site cleavage but also impacts structural transitions into and out of this spliceosome conformation. This function may be critical for splicing in S. cerevisiae under nonoptimal conditions, facilitating use of weak or alternate splice sites, and could have implications for proofreading of spliceosome active site formation. Graphical Abstract Article Summary Pre-mRNA splicing is carried out by large macromolecular machines called spliceosomes which are composed of several snRNAs and dozens of proteins. Despite decades of study, the functions of many splicing factors such as S. cerevisiae Cwc15p remain unknown. Cwc15p is highly conserved among eukaryotes and directly contacts the spliceosome catalytic core. Here, we have used genetic and splicing reporter assays to study the function of Cwc15p during splicing in vivo . We propose that Cwc15p both stabilizes the spliceosome active site during 5’ splice site cleavage and impacts remodeling of that site.