Kurt W. Runge

A two-step model for senescence triggered by a single critically short telomere

Telomeres protect chromosome ends from fusion and degradation. In the absence of a specific telomere elongation mechanism, their DNA shortens progressively with every round of replication, leading to replicative senescence. Here, we show that telomerase-deficient cells bearing a single, very short telomere senesce earlier, demonstrating that the length of the shortest telomere is a major determinant of the onset of senescence. We further show that Mec1p–ATR specifically recognizes the single, very short telomere causing the accelerated senescence. Strikingly, before entering senescence, cells divide for several generations despite complete erosion of their shortened telomeres. This pre-senescence growth requires RAD52 (radiation sensitive) and MMS1 (methyl methane sulfonate sensitive), and there is no evidence for major inter-telomeric recombination. We propose that, in the absence of telomerase, a very short telomere is first maintained in a pre-signalling state by a RAD52–MMS1-dependent pathway and then switches to a signalling state leading to senescence through a Mec1p-dependent checkpoint.

The Yeast Telomere Length Counting Machinery Is Sensitive to Sequences at the Telomere-Nontelomere Junction

ABSTRACT Saccharomyces cerevisiae telomeres consist of a continuous 325 ± 75-bp tract of the heterogeneous repeat TG1-3 which contains irregularly spaced, high-affinity sites for the protein Rap1p. Yeast cells monitor or count the number of telomeric Rap1p molecules in a negative feedback mechanism which modulates telomere length. To investigate the mechanism by which Rap1p molecules are counted, the continuous telomeric TG1-3 sequences were divided into internal TG1-3 sequences and a terminal tract separated by nontelomeric spacers of different lengths. While all of the internal sequences were counted as part of the terminal tract across a 38-bp spacer, a 138-bp disruption completely prevented the internal TG1-3 sequences from being considered part of the telomere and defined the terminal tract as a discrete entity separate from the subtelomeric sequences. We also used regularly spaced arrays of six Rap1p sites internal to the terminal TG1-3 repeats to show that each Rap1p molecule was counted as about 19 bp of TG1-3 in vivo and that cells could count Rap1p molecules with different spacings between tandem sites. As previous in vitro experiments had shown that telomeric Rap1p sites occur about once every 18 bp, all Rap1p molecules at the junction of telomeric and nontelomeric chromatin (the telomere-nontelomere junction) must participate in telomere length measurement. The conserved arrangement of these six Rap1p molecules at the telomere-nontelomere junction in independent transformants also caused the elongated TG1-3 tracts to be maintained at nearly identical lengths, showing that sequences at the telomere-nontelomere junction had an effect on length regulation. These results can be explained by a model in which telomeres beyond a threshold length form a folded structure that links the chromosome terminus to the telomere-nontelomere junction and prevents telomere elongation.

Sir3p phosphorylation by the Slt2p pathway effects redistribution of silencing function and shortened lifespan

An organisms lifespan is modulated by environmental conditions. When nutrients are abundant, the metabolism of many organisms shifts to growth or reproduction at the expense of longer lifespan, whereas a scarcity of nutrients reverses this shift. These correlations suggest that organisms respond to environmental changes by altering their metabolism to promote either reproduction and growth or long life. The only previously reported signaling mechanism involved in this response is the nutrient-responsive insulin/insulin-like growth factor-1 receptor pathway. Here we report another pathway that controls the length of yeast lifespan. Commitment to cell growth activates the Slt2p MAP kinase pathway, which phosphorylates the transcriptional silencing protein Sir3p, resulting in a shorter lifespan. Elimination of the Sir3p phosphorylation site at Ser275 extended lifespan by 38%. Lifespan extension occurs by a mechanism that is independent of suppressing rDNA recombination. Thus, Slt2p is an enzymatic regulator of silencing function that couples commitment to cell growth and shorter lifespan.

The C Terminus of the Major Yeast Telomere Binding Protein Rap1p Enhances Telomere Formation

ABSTRACT The telomeres of most organisms consist of short repeated sequences that can be elongated by telomerase, a reverse transcriptase complex that contains its own RNA template for the synthesis of telomere repeats. In Saccharomyces cerevisiae, the RAP1gene encodes the major telomere binding protein Rap1p. Here we use a quantitative telomere formation assay to demonstrate that Rap1p C termini can enhance telomere formation more than 30-fold when they are located at internal sites. This stimulation is distinct from protection from degradation. Enhancement of formation required the gene for telomerase RNA but not Sir1p, Sir2p, Sir3p, Sir4p, Tel1p, or the Rif1p binding site in the Rap1p C terminus. Our data suggest that Rap1p C termini enhance telomere formation by attracting or increasing the activity of telomerase near telomeres. Earlier work suggests that Rap1p molecules at the chromosome terminus inhibit the elongation of long telomeres by blocking the access of telomerase. Our results suggest a model where a balance between internal Rap1p increasing telomerase activity and Rap1p at the termini of long telomeres controlling telomerase access maintains telomeres at a constant length.

Tel2p, a regulator of yeast telomeric length in vivo, binds to single-stranded telomeric DNA in vitro.

Abstract.The telomeres of the yeast Saccharomyces cerevisiae consist of a duplex region of TG1–3 repeats that acquire a single-stranded 3’ extension of the TG1–3 strand at the end of S-phase. The length of these repeats is kept within a defined range by regulators such as the TEL2-encoded protein (Tel2p). Here we show that Tel2p can specifically bind to single-stranded TG1–3. Tel2p binding produced several shifted bands; however, only the slowest migrating band contained Tel2p. Methylation protection and interference experiments as well as gel shift experiments using inosine-containing probes indicated that the faster migrating bands resulted from Tel2p-mediated formation of DNA secondary structures held together by G-G interactions. Tel2p bound to single-stranded substrates that were at least 19 bases in length and contained 14 bases of TG1–3, and also to double-stranded/single-stranded hybrid substrates with a 3’ TG1–3 overhang. Tel2p binding to a hybrid substrate with a 24 base single-stranded TG1–3 extension also produced a band characteristic of G-G-mediated secondary structures. These data suggest that Tel2p could regulate telomeric length by binding to the 3’ single-stranded TG1–3 extension present at yeast telomeres.

The ZDS1 and ZDS2 proteins require the Sir3p component of yeast silent chromatin to enhance the stability of short linear centromeric plasmids

Abstract.Yeast artificial chromosome (YAC) clones of Saccharomyces cerevisiae containing a centromere, origin of replication, two telomeres and a >50 kb insert of DNA are maintained as normal yeast chromosomes. However, short linear centromeric plasmids of 10–15 kb in size (short YACs) are missegregated at a much higher frequency than long YACs or 10–15 kb circular centromeric plasmids. A search for genes that stabilized short linear centromeric plasmids when present in multiple copies per cell uncovered ZDS1, which reduced the rate at which cells lost the short YAC, increased the fraction of cells that maintained the short YAC and decreased the number of short YACs per cell. Multiple copies of ZDS2, a homolog of ZDS1, had similar effects. Genes near yeast telomeres are transcriptionally silenced by the recruitment of proteins encoded by the SIR2, SIR3 and SIR4 genes (Sir2p, Sir3p and Sir4p). Multiple copies of ZDS1 and ZDS2 caused an increase in telomeric silencing. In addition, ZDS1 and ZDS2 both required the open reading frame encoding the N-terminal 174 amino acids of Sir3p to stabilize short YACs. Thus, the short YAC stability assay revealed a silencing-independent function for the Sir3p N-terminus. Two-hybrid analysis indicated that Zds1p and Zds2p interact with Sir2p, Sir3p, Sir4p or the yeast telomere binding protein Rap1p. Deletion of both ZDS1 and ZDS2 made short YACs, but not a 100 kb YAC, extremely unstable and also caused a 70 bp increase in the length of the telomeric TG1–3 repeats. These data indicate that short YACs can be stabilized by trans-acting factors and suggest that the proteins encoded by ZDS1 and ZDS2 alter short YAC stability by interacting with proteins that function at the telomere.

A new Schizosaccharomyces pombe chronological lifespan assay reveals that caloric restriction promotes efficient cell cycle exit and extends longevity.

We describe a new chronological lifespan (CLS) assay for the yeast Schizosaccharomyces pombe. Yeast CLS assays monitor the loss of cell viability in a culture over time, and this new assay shows a continuous decline in viability without detectable regrowth until all cells in the culture are dead. Thus, the survival curve is not altered by the generation of mutants that can grow during the experiments, and one can monitor the entire lifespan of a strain until the number of viable cells has decreased over 10(6)-fold. This CLS assay recapitulates the evolutionarily conserved features of lifespan shortening by over nutrition, lifespan extension by caloric restriction, increased stress resistance of calorically restricted cells and lifespan control by the AKT kinases. Both S. pombe AKT kinase orthologs regulate CLS: loss of sck1(+) extended lifespan in over nutrition conditions, loss of sck2(+) extended lifespan under both normal and over nutrition conditions, and loss of both genes showed that sck1(+) and sck2(+) control different longevity pathways. The longest-lived S. pombe cells showed the most efficient cell cycle exit, demonstrating that caloric restriction links these two processes. This new S. pombe CLS assay will provide a valuable tool for aging research.

The Vitamin K Oxidoreductase Is a Multimer That Efficiently Reduces Vitamin K Epoxide to Hydroquinone to Allow Vitamin K-dependent Protein Carboxylation

Background: How the vitamin K oxidoreductase (VKORC1) supports vitamin K-dependent protein carboxylation is poorly understood. Results: VKORC1 multimers efficiently perform both reactions that reduce vitamin K, and the inactive monomer in wild type mutant heteromers suppresses reduction. Conclusion: VKORC1 fully reduces vitamin K required for carboxylation. Significance: Multimers are important in VKORC1 mechanism and wild type mutant heteromers impact patients with warfarin resistance. The vitamin K oxidoreductase (VKORC1) recycles vitamin K to support the activation of vitamin K-dependent (VKD) proteins, which have diverse functions that include hemostasis and calcification. VKD proteins are activated by Glu carboxylation, which depends upon the oxygenation of vitamin K hydroquinone (KH2). The vitamin K epoxide (KO) product is recycled by two reactions, i.e. KO reduction to vitamin K quinone (K) and then to KH2, and recent studies have called into question whether VKORC1 reduces K to KH2. Analysis in insect cells lacking endogenous carboxylation components showed that r-VKORC1 reduces KO to efficiently drive carboxylation, indicating KH2 production. Direct detection of the vitamin K reaction products is confounded by KH2 oxidation, and we therefore developed a new assay that stabilized KH2 and allowed quantitation. Purified VKORC1 analyzed in this assay showed efficient KO to KH2 reduction. Studies in 293 cells expressing tagged r-VKORC1 revealed that VKORC1 is a multimer, most likely a dimer. A monomer can only perform one reaction, and a dimer is therefore interesting in explaining how VKORC1 accomplishes both reactions. An inactive mutant (VKORC1(C132A/C135A)) was dominant negative in heterodimers with wild type VKORC1, resulting in decreased KO reduction in cells and carboxylation in vitro. The results are significant regarding human VKORC1 mutations, as warfarin-resistant patients have mutant and wild type VKORC1 alleles. A VKORC1 dimer indicates a mixed population of homodimers and heterodimers that may have different functional properties, and VKORC1 reduction may therefore be more complex in these patients than appreciated previously.

Zinc finger protein Loz1 is required for zinc-responsive regulation of gene expression in fission yeast.

Significance Zinc is an essential nutrient that is a cofactor in a wide range of enzymes and regulatory proteins. However, in excess, zinc is toxic to growth. As a consequence, all cells required mechanisms to maintain an optimal level of zinc. Despite a wealth of knowledge of proteins that use a structural or catalytic zinc cofactor, relatively little is know about the factors that sense and regulate intracellular zinc levels in eukaryotes. This report demonstrates that Loz1, a transcriptional repressor that contains a double C2H2-type zinc finger domain, plays a central role in zinc homeostasis in Schizosaccharomyces pombe. These studies provide important insight into the types of proteins and possible domains that can be used to sense zinc ions. In Schizosaccharomyces pombe, alcohol dehydrogenase 1 (Adh1) is an abundant zinc-requiring enzyme that catalyses the conversion of acetaldehyde to ethanol during fermentation. In a zinc-replete cell, adh1 is highly expressed. However, in zinc-limited cells, adh1 gene expression is repressed, and cells induce the expression of an alternative alcohol dehydrogenase encoded by the adh4 gene. In our studies examining this zinc-dependent switch in alcohol dehydrogenase gene expression, we isolated an adh1Δ strain containing a partial loss of function mutation that resulted in higher levels of adh4 transcripts in zinc-replete cells. This mutation also led to the aberrant expression of other genes that are typically regulated by zinc. Using linkage analysis, we have mapped the position of this mutation to a single gene called Loss Of Zinc sensing 1 (loz1). Loz1 is a 55-kDa protein that contains a double C2H2-type zinc finger domain. The mapped mutation that disrupts Loz1 function leads to an arginine to glycine substitution in the second zinc finger domain, suggesting that the double zinc finger domain is important for Loz1 function. We show that loz1Δ cells hyperaccumulate zinc and that Loz1 is required for gene repression in zinc-replete cells. We also have found that Loz1 negatively autoregulates its own expression. We propose that Loz1 is a unique metalloregulatory factor that plays a central role in zinc homeostasis in S. pombe.

Generation and analysis of a barcode-tagged insertion mutant library in the fission yeast Schizosaccharomyces pombe

BackgroundBarcodes are unique DNA sequence tags that can be used to specifically label individual mutants. The barcode-tagged open reading frame (ORF) haploid deletion mutant collections in the budding yeast Saccharomyces cerevisiae and the fission yeast Schizosaccharomyces pombe allow for high-throughput mutant phenotyping because the relative growth of mutants in a population can be determined by monitoring the proportions of their associated barcodes. While these mutant collections have greatly facilitated genome-wide studies, mutations in essential genes are not present, and the roles of these genes are not as easily studied. To further support genome-scale research in S. pombe, we generated a barcode-tagged fission yeast insertion mutant library that has the potential of generating viable mutations in both essential and non-essential genes and can be easily analyzed using standard molecular biological techniques.ResultsAn insertion vector containing a selectable ura4+ marker and a random barcode was used to generate a collection of 10,000 fission yeast insertion mutants stored individually in 384-well plates and as six pools of mixed mutants. Individual barcodes are flanked by Sfi I recognition sites and can be oligomerized in a unique orientation to facilitate barcode sequencing. Independent genetic screens on a subset of mutants suggest that this library contains a diverse collection of single insertion mutations. We present several approaches to determine insertion sites.ConclusionsThis collection of S. pombe barcode-tagged insertion mutants is well-suited for genome-wide studies. Because insertion mutations may eliminate, reduce or alter the function of essential and non-essential genes, this library will contain strains with a wide range of phenotypes that can be assayed by their associated barcodes. The design of the barcodes in this library allows for barcode sequencing using next generation or standard benchtop cloning approaches.