Kluyveromyces lactis zymocin mode of action is linked to RNA polymerase II function via Elongator

The putative Kluyveromyces lactis zymocin target complex, TOT, from Saccharomyces cerevisiae comprises five Tot proteins, four of which are RNA polymerase II (RNAP II) Elongator subunits. Recently, two more Elongator subunit genes, ELP6 (TOT6) and ELP4 (TOT7), have been identified. Deletions of both TOT6 and TOT7 result in the complex tot phenotype, including resistance to zymocin, thermosensitivity, slow growth and hypersensitivity towards drugs, thus reinforcing the notion that TOT/Elongator may be crucial in signalling zymocicity. Mutagenesis of ELP3/TOT3, the Elongator histone acetyltransferase (HAT) gene, revealed that zymocin sensitivity could be uncoupled from Elongator wild-type function, indicating that TOT interacts genetically with zymocin. To test the possibility that zymocin functions by affecting RNAP II activity in a TOT/Elongator-dependent manner, global poly(A)+ mRNA levels were found to decline drastically on zymocin treatment. Moreover, cells overexpressing Fcp1p, the RNAP II carboxy-terminal domain phosphatase, acquired partial zymocin resistance, whereas cells underproducing RNAP II became zymocin hypersensitive. This suggests that zymocin may convert TOT/Elongator into a cellular poison toxic for RNAP II function and eventually leading to the observed G1 cell cycle arrest.     

A second essential function of the Est1-binding arm of yeast telomerase RNA

The enzymatic ribonucleoprotein telomerase maintains telomeres in many eukaryotes, including humans, and plays a central role in aging and cancer. Saccharomyces cerevisiae telomerase RNA, TLC1, is a flexible scaffold that tethers telomerase holoenzyme protein subunits to the complex. Here we test the hypothesis that a lengthy conserved region of the Est1-binding TLC1 arm contributes more than simply Est1-binding function. We separated Est1 binding from potential other functions by tethering TLC1 to Est1 via a heterologous RNA-protein binding module. We find that Est1-tethering rescues in vivo function of telomerase RNA alleles missing nucleotides specifically required for Est1 binding, but not those missing the entire conserved region. Notably, however, telomerase function is restored for this condition by expressing the arm of TLC1 in trans. Mutational analysis shows that the Second Essential Est1-arm Domain (SEED) maps to an internal loop of the arm, which SHAPE chemical mapping and 3D modeling suggest could be regulated by conformational change. Finally, we find that the SEED has an essential, Est1-independent role in telomerase function after telomerase recruitment to the telomere. The SEED may be required for establishing telomere extendibility or promoting telomerase RNP holoenzyme activity.     

Identification of the sequences required for chromosomal replicator function in Kluyveromyces lactis

The analysis of replication intermediates of a Kluyveromyces lactis chromosomal autonomous replicating sequence (ARS), KARS101, has shown that it is active as a chromosomal replicator. KARS101 contains a 50 bp sequence conserved in two other K. lactis ARS elements. The deletion of the conserved sequence in KARS101 completely abolished replicator activity, in both the plasmids and the chromosome. Gel shift assays indicated that this sequence binds proteins present in K. lactis nuclear extracts, and a 40 bp sequence, previously defined as the core essential for K. lactis ARS function, is required for efficient binding. Reminiscent of the origin replication complex (ORC), the binding appears to be ATP dependent. A similar pattern of protection of the core was seen with in vitro footprinting. KARS101 also functions as an ARS sequence in Saccharomyces cerevisiae. A comparative study using S. cerevisiae nuclear extracts revealed that the sequence required for binding is a dodecanucleotide related to the S. cerevisiae ARS consensus sequence and essential for S. cerevisiae ARS activity.     

The 5' guanosine tracts of human telomerase RNA are recognized by the G-quadruplex binding domain of the RNA helicase DHX36 and function to increase RNA accumulation

Telomerase promotes telomere maintenance by copying a template within its integral RNA subunit to elongate chromosome ends with new telomeric repeats. Motifs have been defined within the telomerase RNA that contribute to mature RNA accumulation, holoenzyme catalytic activity, or enzyme recruitment to telomeres. Here, we describe a motif of human telomerase RNA (hTR), not previously characterized in a cellular context, comprised of several guanosine tracts near the RNA 5' end. These guanosine tracts together are recognized by the DEXH box RNA helicase DHX36. The helicase domain of DHX36 does not mediate hTR binding; instead, hTR interacts with the N-terminal accessory domain of DHX36 known to bind specifically to the parallel-strand G-quadruplex substrates resolved by the helicase domain. The steady-state level of DHX36-hTR interaction is low, but hTR guanosine tract substitutions substantially reduce mature hTR accumulation and thereby reduce telomere maintenance. These findings suggest that G-quadruplex formation in the hTR precursor improves the escape of immature RNP from degradation, but subsequently the G-quadruplex may be resolved in favor of a longer terminal stem. We conclude that G-quadruplex formation within hTR can stimulate telomerase-mediated telomere maintenance.     

The pheromone response pathway of Kluyveromyces lactis

The mating pheromone response pathway in Saccharomyces cerevisiae is one of the best understood signalling pathways in eukaryotes. Comparison of this system with pathways in other fungal species has generated surprises and insights. Cloning and targetted disruption of genes encoding components of the pheromone response pathway has allowed the attribution of specific functions to these signal transduction components. In this review we describe current knowledge of the Kluyveromyces lactis mating system, and compare it with the well-understood S. cerevisiae pathway, emphasizing the similarities and differences in the heterotrimeric G protein activity. This mating pathway is controlled positively by both the Galpha and the Gbeta subunits of the heterotrimeric G protein.     

The Kluyveromyces lactis gamma-toxin targets tRNA anticodons

Kluyveromyces lactis killer strains secrete a heterotrimeric toxin (zymocin), which causes an irreversible growth arrest of sensitive yeast cells. Despite many efforts, the target(s) of the cytotoxic gamma-subunit of zymocin has remained elusive. Here we show that three tRNA species tRNA(Glu)(mcm(5)s(2)UUC), tRNA(Lys)(mcm(5)s(2)UUU), and tRNA(Gln)(mcm(5)s(2)UUG) are the targets of gamma-toxin. The toxin inhibits growth by cleaving these tRNAs at the 3' side of the modified wobble nucleoside 5-methoxycarbonylmethyl-2-thiouridine (mcm(5)s(2)U). Transfer RNA lacking a part of or the entire mcm(5) group is inefficiently cleaved by gamma-toxin, explaining the gamma-toxin resistance of the modification-deficient trm9, elp1-elp6, and kti11-kti13 mutants. The K. lactis gamma-toxin is the first eukaryotic toxin shown to target tRNA.     

Escherichia coli DbpA is a 3' --> 5' RNA helicase

Previous work has demonstrated that Escherichia coli DbpA is a nonprocessive RNA helicase that can disrupt short RNA helices on either the 5' side or 3' side of hairpin 92 of 23S rRNA. Here the directionality of the helicase activity of DbpA was determined by using substrates containing a short reporter helix in the presence of a second adjacent helix of varying stability placed either 5' or 3' of the reporter helix. When the second helix was on the 5' side of the reporter helix, it had no effect on the dissociation rate of the reporter helix. However, when the second helix was on the 3' side of the reporter helix, its dissociation rate determined the dissociation rate of the reporter helix. This defines DbpA as a 3' --> 5' helicase. Like other helicases, DbpA requires a single-stranded RNA loading site on the 3' side of the duplex for disruption to be observed. Since the loading site could be on either strand of the helix that was disrupted, hairpin 92 does not influence the directionality of the helicase but only aids in targeting RNA substrates.