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Molecular and Cellular Biology, January 2002, p. 421-429, Vol. 22, No. 2
0270-7306/01/$04.00+0     DOI: 10.1128/MCB.22.2.421-429.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

hpr1 Affects Ribosomal DNA Recombination and Cell Life Span in Saccharomyces cerevisiae

Department of Biochemistry and Kaplan Comprehensive Cancer Center, New York University School of Medicine, New York, New York 10016

Received 19 June 2001/ Returned for modification 30 July 2001/ Accepted 8 October 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
Multiple genetic pathways have been shown to regulate life span and aging in the yeast Saccharomyces cerevisiae. Here we show that loss of a component of the RNA polymerase II complex, Hpr1p, results in a decreased life span. Although hpr1 mutants have an increased rate of recombination within the ribosomal DNA (rDNA) array, this is not accompanied by an increase in extrachromosomal rDNA circles (ERCs). Analyses of mutants that affect replication of the rDNA array and suppressors that reverse the phenotypes of the hpr1 mutant show that the reduced life span is associated with increased genomic instability but not with increased ERC formation. The hpr1 mutant acts in a pathway distinct from previously described mutants that reduce life span.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
Cellular or organismal life span is determined by genetic and extrinsic factors. Toward the end of the life span, cells often deteriorate, giving rise to the phenotypes associated with aging. Recently, experimental systems have been developed that now permit the identification of genes that influence life span. Often, although not always, mutations that reduce life span result in the phenotype of an early appearance of aging features (32). The ability to tolerate stress and the effects of caloric restriction are correlated with increased life span in mice, Caenorhabditis elegans, Drosophila melanogaster, and Saccharomyces cerevisiae (for reviews, see references 18, 23, 33, 51, and 57). Recognition of the contribution that these processes have on life span has led to an identification of some of the genetic components underlying life span and senescence in various experimental organisms (12, 19).

In addition to the above genetic factors, in the yeast S. cerevisiae life span is influenced by gene silencing. This is thought to act by silencing within the ribosomal DNA (rDNA) array, which is composed of 100 to 200 tandem repeats. The Sir2 protein, encoding an NAD-dependent histone deacetylase (22), is localized to the silenced genomic regions that are the telomeres (16), the HML and HMR mating-type genes (40), and the rDNA array to form a silenced state of chromatin (4, 25, 50, 52). The silenced rDNA array is repressed for recombination (15). The products of rDNA recombination, excised circles with rDNA repeats, which are termed ERCs (for extrachromosomal rDNA circles), have been suggested to be correlated with aging, but this metric of aging has been challenged in recent studies (21, 27, 28). Nonetheless, instability within the rDNA has been correlated with reduced life span in a number of mutants, including the sgs1 and sir2 mutants (9, 24, 31, 42, 48). Sgs1p is the yeast homolog of the Escherichia coli RecQ helicase and the human BLM and WRN proteins. Since the topoisomerase genes TOP1, TOP2, and TOP3 function in maintaining wild-type levels of recombination within the rDNA and the Top2 and Top3 proteins interact with the Sgs1 protein (13, 56), other mutants that affect rDNA stability may have an interaction with the topoisomerase genes. To further explore the relationship between rDNA instability and life span, we examined the hpr1 mutant of S. cerevisiae.

The yeast hyperrecombination mutant hpr1 increases intrachromosomal recombination between non-rDNA direct repeats by almost 1,000-fold (2). In those studies we noted a slight enhancement of recombination within the rDNA array in the hpr1 mutant strain (2). Other phenotypes of the hpr1 mutant also suggested that Hpr1p had a function in the stabilization of the rDNA array. First, a full complement of topoisomerase activities is necessary for viability in an hpr1 background (2). Second, hpr1 cells have aberrant ring-shaped nucleoli and general defects in rRNA processing when shifted to a nonpermissive growth temperature (37°C) (46). Although the exact biochemical function of Hpr1p remains unclear, it has a functional role in RNA polymerase II transcription, and most genetic suppressors of hpr1-stimulated hyperrecombination are mutations in components of the RNA polymerase II transcription machinery (10, 11, 37, 38, 45, 54). Furthermore, the hyperrecombination phenotype of hpr1 is dependent on RNA polymerase II transcription (10), specifically transcriptional elongation (6). Hpr1p has recently been identified as a component of at least two unique protein complexes, each with both biochemical and genetic associations with RNA polymerase II transcription. One biochemically defined complex containing Hpr1p, Paf1p, Ccr4p, and Cdc73p appears to be a subunit of an alternative RNA polymerase II holoenzyme with distinct regulatory functions (5), while another biochemically defined complex is composed of Hpr1p, Tho2p, Mft1p, and Thp2 and functions in transcriptional elongation (7).

In this study we have reinvestigated the effect of the hpr1 mutation on rDNA recombination. We demonstrate that hpr1 does indeed affect the stability of the rDNA repeat array and life span in yeast in an ERC-independent process. The hpr1 effect on life span is independent of other mutants known to affect yeast life span and suggests that transcription effects have an important influence on cellular life span.

	MATERIALS AND METHODS

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Strains and growth media. The S. cerevisiae strains used in this study are listed in Table 1. All strains are isogenic and have the W303 RAD5⁺ background. The W303R strain contains a single copy of ADE2 inserted into the rDNA repeat array and is described elsewhere (24). The strains with the ADE2 marker inserted into the rDNA array were used for obtaining rDNA recombination rates. The non-ADE2 marker strains were used for life span analysis. The fob1::URA3 disruption was generated by a targeted PCR method described earlier (3, 41). URA3 was amplified from the pRS316 vector. Primers were designed such that 40 nucleotides of homology to FOB1 were incorporated at the ends of the URA3 amplification. The resulting disruption deleted the entire FOB1 gene except for the first and last 40 nucleotides. Descriptions of the hpr1 and soh1 null allele strains can be found elsewhere (2, 10). The sgs1::URA3 disruption and the W303R strain were kindly provided by R. Rothstein and L. Guarente, respectively. Strains were cultured in standard yeast extract-peptone-dextrose (YPD) medium containing 2% glucose at 30°C unless otherwise noted (20).

At least 50 mother cells were used from each strain to generate the life span curves and to determine average longevity. The Mann-Whitney test was used to determine statistical significance between the different average life spans. Statistical differences in mortality rates at specified generations were analyzed by using the log-rank test (35, 36).

Determination of rDNA recombination rates. Mitotic rDNA recombination rates were determined as described previously (8). The loss of an ADE2 marker integrated into the rDNA array was used to measure recombination. Strains were grown to mid-log phase in liquid YPD medium, diluted, and plated onto solid YPD. Colonies were grown at 30°C for 2 days and then transferred to 4°C for 4 days prior to analysis. Half-sectored red and white colonies indicate that the ADE2 marker was lost in the first cell division after plating. Partially red colonies indicate that the marker was lost after the first cell division after plating. Fully red colonies can only be the result of marker loss prior to plating and are not used in the analysis. The recombination rate is determined by considering only the first cell division after plating and is calculated by dividing the total number of half-sectored colonies by the total number of colonies (white plus half-sectors plus partial sectors). The Student’s t test was used to analyze significance between rDNA recombination rates.

Segregation of old cells. The segregation of old cells from the majority of young cells in a mid-log phase culture was accomplished by using the techniques described in detail elsewhere (47, 49). Briefly, cells were cultured at 30°C in liquid YPD medium to mid-log phase (optical density at 600 nm [OD₆₀₀] = 0.7). Cells were collected by centrifugation, washed twice in phosphate-buffered saline (PBS) buffer, and resuspended in 1 ml of PBS. Approximately 10 mg of sulfo-NHS-LC-biotin (Pierce) was added to the cells, and the mixture as gently shaken at room temperature for 15 min. Cells were washed eight times in 1 ml of PBS and then resuspended in 1 ml of YPD liquid medium. Then, 10⁸ cells from this biotin-labeled culture were resuspended into 1 liter of YPD containing 3% glucose, followed by growth at 30°C overnight for ca. 12 to 13 h (cultures were not allowed to exceed an OD₆₀₀ of 1.0). Cells were collected by centrifugation and resuspended in 40 ml of cold PBS. Next, 300 µl of streptavidin-coated magnetic beads (PerSeptive Biosystems; 5 µg/µl, washed and equilibrated with PBS) was added to the cells, and the cells were kept on ice for 4 h with occasional mixing. Cells were distributed to 10-ml test tubes and placed in a magnetic sorter for 15 min at 4°C. Free cells were carefully removed with a pipette. The bead-bound cells were then resuspended in 10 ml of ice-cold YPD and placed back into the magnetic sorter at 4°C. This washing procedure was repeated eight times before the cells were pooled and stored on ice prior to DNA isolation. An aliquot of cells was used for staining with Calcofluor and examination with a fluorescence microscope to count the number of bud scars per cell. Cell from the old cell fraction contained 8 to 10 staining bud scars per cell, indicating that the age of this cell fraction was 8 to 10 generations.

Old and young cell DNA isolation and ERC quantitation. DNA preparations from old cells were performed immediately after sorting. Old and young cells were washed in 1 ml of double-distilled water, centrifuged, and resuspended in 0.5 ml of sorbitol solution (1 M sorbitol, 0.1 EDTA [pH 8.0]) containing 30 µg of zymolyase 100T (U.S. Biological)/ml. Then, 0.05 ml of 0.28 M ß-mercaptoethanol was added, and the cells were incubated at 37°C for 25 min. The resulting spheroplasts were gently centrifuged and resuspended in 0.5 ml of 50 mM Tris (pH 7.8)-20 mM EDTA. The spheroplasts were lysed by adding 0.05 ml of 10% sodium dodecyl sulfate and incubating them at 65°C for 20 min. Then, 0.2 ml of 5 M potassium acetate was added, followed by gentle mixing and incubation on ice for 30 min. Tubes were centrifuged at top speed for 5 min, the supernatant was collected, and the DNA was precipitated with an equal volume of isopropanol. The DNA pellet was resuspended in 0.05 ml of TE. ERCs were resolved by loading equal volumes of DNA on 0.7% agarose gels without ethidium bromide at 1 V/cm for 20 to 24 h. rDNA species were detected by Southern blotting and hybridization to the radiolabeled rDNA fragment, RDN25. Autoradiographs were visualized by using a Bio-Rad phosphorimager, and quantitation was performed by using NIH Image 1.6. ERC levels in old cells were normalized against the chromosomal rDNA. ERC levels in young cells were quantitated by normalizing against a single-copy chromosomal sequence, ACT1. Equal volumes of DNA were digested with EcoRI and resolved on a 1% agarose gel. ACT1 was detected by Southern blotting and hybridization to a radiolabeled probe generated from the 0.6-kb internal ClaI fragment of ACT1.

Terminal morphologies. Terminal morphologies were determined as described earlier (34). Small budded cells were defined as budding cells where the bud was less than one-fourth the diameter of the adjoining mother cell. Large budded cells were defined as budding cells where the bud was greater than or equal to one-fourth the diameter of the adjoining mother cell.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
hpr1 cells have an increased rate of rDNA mitotic intrachromosomal recombination. Loss-of-function mutations in the HPR1 gene result in a dramatic increase in mitotic intrachromosomal recombination between direct repeats in non-rDNA chromosomal locations (2). At the time, we had a suggestive effect of a hpr1 mutation on recombination within the rDNA repeat array, but the recombination reporter was not optimal. To more accurately determine whether a hpr1 mutant had an increased recombination rate in the rDNA, we measured rDNA recombination by monitoring the loss of an ADE2 marker inserted into the repeat array, by using a half-sector protocol that measures recombination only in the first cell division after plating (see Materials and Methods). We observed that the hpr1 strain has a significant increase in rDNA recombination compared to the HPR1 control strain (Table 2). hpr1 loses the ADE2 marker at a rate that is threefold higher than the rate with HPR1 (P < 0.005).

The average longevity of hpr1 cells is reduced.

View larger version (19K): [in this window] [in a new window]   FIG. 1. hpr1 cells have a reduced average life span that is FOB1 independent. (A) The life spans for wild-type (WT; 580-10D), hpr1 (HFY824-1A), and cdc73 (RMY212-12D) cells were determined. The mean life spans for the wild-type (n = 82), hpr1 (n = 53), and cdc73 (n = 56) strains were 20.1, 13.7, and 15.2 generations, respectively. (B) The life spans for the fob1 (RMY178-1A) and hpr1 fob1 (RMY151-11B) strains were determined and are shown with the wild-type and hpr1 data from panel A. The mean life spans for the fob1 (n = 56) and hpr1 fob1 (n = 50) strains were 26.9 and 12.4 generations, respectively. The life spans of individual haploid mother cells were determined as described in Materials and Methods.

View larger version (41K): [in this window] [in a new window]   FIG. 2. ERC accumulation in young and old cells. (A) DNA was isolated from young cells (logarithmically growing cultures) and old cells (ca. 8 to 10 generations old) to determine the levels of ERCs in each strain: wild type (580-10D), hpr1 (HFY824-1A), sgs1 (RMY059-2B), hpr1 sgs1 (RMY058-5A), fob1 (RMY178-1A), and hpr1 fob1 (RMY151-11B). Old cells were sorted, and DNA was electrophoresed as described in Materials and Methods. Transfers were probed with rDNA sequence RDN25. The circle indicates chromosomal rDNA; the arrows indicate two identifiable ERC species. (B) ERC levels of each mutant relative to the wild type in young cells. The two visible ERC species were averaged and quantitated against a single-copy chromosomal sequence (ACT1). The levels indicated are the averages from three additional independent experiments. The error bars represent the standard deviations from each set of experiments.

hpr1-mediated rDNA hyperrecombination and life span is FOB1-independent. FOB1 is required for the replication fork block that is observed within the rDNA array during replication (29, 30). A fob1 mutation results in a decreased rDNA recombination rate, a decreased amount of ERCs, and an increased life span (9). This indicates that the replication block mediated by Fob1p is necessary for the majority of the rDNA recombination events and consequently for ERC formation in wild-type cells. We used the hpr1 fob1 double mutant to determine whether the rDNA recombination events observed in hpr1 cells are dependent on the Fob1p-mediated replication fork block. The rDNA recombination rate in the hpr1 fob1 double mutant is statistically the same as that obtained for the hpr1 single mutant (Table 2). This suggests that the majority of rDNA recombination events in hpr1 are independent of FOB1.

Since the hpr1 fob1 double mutant has levels of rDNA recombination similar to those of the hpr1 strain, we examined whether the double mutant could generate ERCs in a FOB1-independent manner. The hpr1 fob1 double mutant has almost no detectable ERCs in unsorted young cells and is indistinguishable from the fob1 single mutant (Fig. 2A). Quantitation of the ERC levels in these two strains confirms this observation (Fig. 2B). Therefore, the formation of ERCs in hpr1 cells is dependent on FOB1, in spite of rDNA recombination being FOB1 independent. This reinforces the observation that hpr1-mediated rDNA recombination is not conservative (44) and does not give reciprocal products expected from a crossing over. Nonconservative recombination would result in the absence of ERCs. Other types of nonconservative recombination include expansions and contractions of repeat sequence tracts during replication slippage events and changes in the number of rDNA array units through gene conversion events (14).

As fob1 suppresses the formation of ERCs in hpr1 cells, we examined whether a fob1 mutation would suppress the decreased life span of the hpr1 mutant. Figure 1B and Table 3 show that the life span of the hpr1 fob1 double mutant is not significantly different from that of the hpr1 single mutant. Taken together, these data indicate that the increased rDNA recombination rate and the decreased life span observed in hpr1 are independent of FOB1 and are not correlated with ERC formation.

hpr1 has additive effects with both sgs1 and sir2 for rDNA recombination and life span. The decreased life span of the hpr1 mutant is most likely due to the combined effects of genomic instability both within the rDNA array and in non-rDNA chromosomal regions. Another mutant, sgs1, also displays genetic instability within and outside of the rDNA repeat array (13, 55), as well as a decrease in life span (48). We examined the hpr1 sgs1 double mutant to determine if these two genes acted together or separately in determining life span. The effect of both mutations on the rDNA recombination rate of the hpr1 sgs1 double mutant was additive (P < 0.05) (Table 2). The hpr1 sgs1 double mutant also has a significantly decreased life span compared to the life spans of the sgs1 and hpr1 single mutants (P < 0.001) (Fig. 3). The reduction in average life span of the hpr1 sgs1 mutant is the product of the reductions in life span of the hpr1 and sgs1 mutants, showing that these genes act independently on life span (Table 3).

View larger version (17K): [in this window] [in a new window]   FIG. 3. Additive effects of the sgs1 and hpr1 mutations on life span. The life spans for the sgs1 (RMY059-2B) and hpr1 sgs1 (RMY058-5A) strains were determined and are shown with the hpr1 data from Fig. 1. The mean life spans of the sgs1 (n = 78), sgs1 hpr1 (n = 64), and hpr1 (n = 53) strains were 8.3, 5.0, and 13.7 generations, respectively.

The sir2 mutant has increased genetic instability within the rDNA as well as a decreased life span. In addition, the sir2 mutant displays a general decrease in transcriptional silencing of RNA polymerase II-transcribed genes when inserted into the rDNA repeat array. Since HPR1 has a role in transcription and in the maintenance of rDNA stability and wild-type life spans, the relationship between HPR1 and SIR2 in controlling rDNA stability, life span, and transcriptional silencing was examined. The results of hpr1 sir2 mutant analyses show that HPR1 functions independently of SIR2 in maintaining rDNA stability and normal life span. The hpr1 sir2 double mutant displays a small but significant (P < 0.05) increase in rDNA recombination over the sir2 single mutant (Table 2), indicating separate contributions of hpr1 and sir2 to rDNA instability. These data suggested that the hpr1 sir2 double mutant would have a shorter life span than either single mutant. Figure 4 shows that this is indeed the case. The hpr1 sir2 life span is significantly shorter than both the sir2 life span (P < 0.001) and the hpr1 life span (P < 0.001), indicating that HPR1 and SIR 2 promote wild-type life spans through different pathways. Table 3 shows that the reduction in the average life span of the hpr1 sir2 double mutant is the product of the reduction in average life spans of the hpr1 and sir2 mutants, indicating independent influences on life span.

View larger version (17K): [in this window] [in a new window]   FIG. 4. Additive effects of the sir2 and hpr1 mutations on life span. The life spans for wild-type (WT; 580-10D), hpr1 (HFY824-1A), sir2 (RMY206-5B), and hpr1 sir2 (RMY207-3A) strains were determined. The mean life spans for the wild-type (n = 50), hpr1 (n = 56), sir2 (n = 58), and hpr1 sir2 (n = 60) strains were 21.6, 13.8, 12.8, and 8.2 generations, respectively.

Old hpr1 cells display terminal phenotypes characteristic of old wild-type cells. The terminal morphology of the dividing yeast mother cell can give information on whether cell death is stochastic and age independent or whether it is related to the aging processes (34). Mother cells from wild-type yeast strains usually cease division as unbudded cells in G₁ at the end of their life span. This unbudded terminal morphology comprises the majority of cell deaths for both short-lived (young, 75% of the maximal life span) and long-lived (old, >75% of the maximal life span) yeast cells (34) (Fig. 5). Analysis of the terminal morphologies of young and old hpr1 cells showed that the majority of terminal phenotypes of young hpr1 cells were as budded cells. Since this terminal G₂ arrest is not as common in young wild-type cells, young hpr1 cells may be dying due to stochastic and age-independent mechanisms. However, the majority of old hpr1 cells display an unbudded terminal phenotype similar to that of old wild-type cells. Therefore, two different factors may be operating in the determination of the average hpr1 life span. The first may be age independent and more related to DNA damage or blocked transcription that leads to a G₂ arrest-like phenotype, while the second factor seems to be age dependent and related to the wild-type aging process.

View larger version (40K): [in this window] [in a new window]   FIG. 5. Terminal morphologies of wild-type (WT) and hpr1 cells. The terminal morphologies for wild-type and hpr1 strains were obtained from the same mother cells used to generate the life span curves in Fig. 4 (wild type; 580-10D, n = 50; hpr1, HFY824-1A, n = 56). Terminal morphologies are defined as either unbudded, budded small, or budded large (see Materials and Methods). The fraction of each of these terminal phenotypes was calculated for both young (75% maximum life span) and old (>75% maximum life span) cells. The maximum life span is the average life span of the oldest 10% of cells in the experiment. The values for 75% of the maximum life span for wild-type and hpr1 strains were 23 and 20 generations, respectively.

soh1 suppresses hpr1-mediated rDNA hyperrecombination and increased mortality rate of young cells. The soh1 mutation was identified in a selection for hpr1 suppressor mutants. soh1 suppresses 90% of hpr1-mediated recombination events of non-rDNA origin (10, 11). soh1 also suppresses the hpr1 requirement for all three functional topoisomerase genes. Soh1p is connected to the RNA polymerase II machinery, and the human counterpart is part of the mediator complex (17). We wanted to determine whether the soh1 mutation also suppresses hpr1-mediated rDNA recombination and the decrease in life span. The soh1 mutant has a wild-type rate of rDNA recombination (Table 2). The rDNA recombination rate of the hpr1 soh1 double mutant is indistinguishable from the wild-type and soh1 rates, showing that the soh1 mutation also suppresses the hpr1-mediated increase in rDNA recombination.

Although the soh1 mutant has a wild-type rDNA recombination rate, the life span in this strain is slightly decreased compared to the wild type (Fig. 6A) (P < 0.01). The effect of the soh1 mutation is most acutely observed in the viability of older cells, a finding similar to what we observed in the cdc73 mutant. The soh1 hpr1 double mutant has an average life span of 15.2 generations, which is not significantly different from that of the hpr1 average life span (13.7 generations) (Fig. 6A and Table 3). By this measure, it cannot be said that soh1 suppresses the overall life span decrease of the hpr1 mutant. However, the shape of the curves shows that the soh1 mutation affects the mortality rates of young hpr1 cells. The mortality rate at each generation for hpr1, and hpr1 soh1 cells is shown in Fig. 6B. A comparison of the mortality rates of the first six generations shows that the hpr1 strain has a significantly increased mortality compared to the hpr1 soh1 double mutant strain (P < 0.001). After the sixth generation, the mortality rates between hpr1 and hpr1 soh1 cells are not significantly different. We conclude that the soh1 mutation suppresses the increased early mortality rate of hpr1 strains but has no effect on the mortality rate during the later phase of the life span.

View larger version (16K): [in this window] [in a new window]   FIG. 6. soh1 suppression of the hpr1-reduced life span. (A) The life spans for soh1 (HFY1002-22A) and hpr1 soh1 (RMY125-7A) strains were determined. The wild-type (wt) and hpr1 data from Fig. 1 are reproduced here for comparison. The mean life spans were as follows: wild type, 20.3 (n = 82); hpr1, 13.7 (n = 53); soh1, 15.4 (n = 57); and hpr1 soh1, 15.2 (n = 60). (B) The increased early mortality rate of hpr1 is suppressed by soh1. Natural logarithms of age-specific mortality rates were calculated for both hpr1 and hpr1 soh1 strains. The log-rank test was used to determine the statistical significance between the early mortality rates (see Materials and Methods).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

hpr1-reduced life span and genomic instability. In hpr1 mutant strains, direct repeats are unstable and deletions occur at approximately a 1,000-fold-increased rate (1, 39). This occurs through DNA homology and requires the homologous recombination repair gene RAD52 (1). Although the events occur through homologous recombination, they are not conservative and do not produce the reciprocal product which is an excised circle containing the deleted DNA (44). In terms of recombination within the rDNA this type of recombination would not give an ERC product. This is precisely what we have observed; hpr1 strains have an increase in rDNA recombination without an increase in ERCs in young or old cell populations. The fact that there is a reduction in life span without an increase in ERCs argues that, in the hpr1 mutant, life span reduction is not related to ERC production. This is further substantiated by the finding that a fob1 mutation eliminates all detectable ERCs and yet has no effect on the reduced life span of hpr1 cells. This does not mean that increased instability within the rDNA array and at other genomic sites is not related to the reduction in life span. The soh1 mutation suppresses hpr1-induced recombination between rDNA repeats and suppresses 90% of the hpr1-induced recombination events between non-rDNA direct repeats (11). soh1 also suppresses the increased early mortality of hpr1 cells. This correlation suggests that in hpr1 cells, reduced life span may be linked to genomic instability. The fact that the hpr1 soh1 double mutant still has a reduced average life span suggests that this reduction in life span could primarily be due to genomic instability that is not suppressed by soh1.

The hpr1 life span curve is distinct in that young cells are particularly at risk for death. It is this increased mortality rate in young cells that is suppressed by the soh1 mutation. Since we have argued that soh1 suppresses genomic instability, this would suggest that young cells have an increased sensitivity to the rate of genomic instability. The mortality rate of young hpr1 cells is similar to that of the sgs1 mutant (Fig. 3). Both mutant strains may experience early sensitivity to spontaneous DNA damage, which is manifested as hyperrecombination and increased cell death. Recent studies on the life span of the sgs1 mutant have led to the conclusion that the early part of the life span curve is the result of DNA damage, while the late part of the curve is the result of age-related death (34). However, the hpr1 mutant has no DNA damage-sensitive phenotype (1, 2), while the sgs1 mutant is sensitive to DNA-damaging agents (43). This reinforces the conclusion that each mutant contributes independently to the rDNA hyperrecombination and reduced life span and shows that there are independent mechanisms that contribute to life span that are related to spontaneous DNA damage.

The terminal phenotypes of mother cells after they have ceased dividing may provide clues as to whether the majority of cell deaths are due to age-independent processes such as DNA damage or whether the deaths can be attributed to wild-type aging processes (34). hpr1 cells that die at a young generation tend to die as G₂-arrested budded cells. This is opposite of the terminal phenotypes that are observed for young wild-type cells, which have a greater tendency to die as G₁-arrested unbudded cells. This suggests that young hpr1 cells die from different causes than those experienced by young wild-type cells. As we have argued above, we believe that this is the genomic instability that results from DNA replication complexes passing through stalled RNAPII complexes. In contrast, the distribution of unbudded to budded cells among old dying hpr1 cells is more similar to the distribution observed for old wild-type cells. This indicates that young dying hpr1 cells may be dying from mechanisms related to DNA damage, while old dying hpr1 cells may be dying from mechanisms more related to wild-type aging. Therefore, at least one component of the hpr1 life span curve seems to be related to wild-type aging mechanisms.

Transcription and life span. Hpr1p is part of an RNA polymerase II complex in a subcomplex with Cdc73p, Paf1p, and Ccr4p (5). Mutants in any one of the genes encoding these proteins are fully viable under normal growth conditions, but double mutants grow poorly or are inviable. We examined the cdc73 mutant and found that it has a reduced life span. This reduction is not readily apparent from inspection of colonies grown on rich medium. The life span curve is unusual in that the young cells have the same viability potential as wild-type cells until ca. 12 generations have passed, and then the viability of successive generations rapidly declines. We do not know the source of the inviability, but we suggest that it reflects the accumulation of some global damage to the cell.

A similar, but not so accentuated, life span curve was observed with the soh1 mutant. hSoh1 has been found in the human mediator complex of RNA polymerase II (17), and in yeast SOH1 has been related genetically to the RNA polymerase II complex and in particular to the CTD tail (10). Hpr1p is part of RNA polymerase II complexes, and in the mutant transcription elongation is affected (6). Our results suggests that modest transcription mutants can have a significant impact on cellular life span and that defects arising first as impairments in transcription can set off a cascade of events that leads to genomic instability and reduced generative potential of a cell. This highlights the multiple mechanisms that can compromise the cellular life span.

Transcriptional regulation through SIR2 has been linked to aging in yeast, as well as in C. elegans, and may function to couple life span to nutrient availability in these organisms (31, 53). Our results suggest that additional transcriptional components influence life span.

	ACKNOWLEDGMENTS

 
We thank L. Guarente for the yeast strain W303R and for the generous gift of the biotin magnetic beads. We thank E. Nudler for comments and critical reading of the manuscript.

This work was supported by grant GM30439 from the National Institutes of Health.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Biochemistry, NYU School of Medicine, 550 First Ave., New York, NY 10016. Phone: (212) 263-5778. Fax: (212) 263-8166. E-mail: hannah.klein{at}med.nyu.edu.

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Top Abstract Introduction Materials and Methods Results Discussion References

 
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