Figure 1.
Heterochromatin levels are important for longevity and muscle integrity.
Percent survival of adult female flies of indicated genotypes at 25°C. Flies had been made coisogenic by extensive outcrossing (see Methods). n donates the number of flies counted. p values are from Log rank analysis. (A) Flies carrying one copy of hsp70-HP1 (expressing more HP1) were longer lived (p = 6.31×10−24), and flies heterozygous for Su(var)2055 (loss-of-function allele) were shorter lived (p = 2.03×10−86) when compared with wild-type “+/+” controls. (B) Flies heterozygous for hopTum-l (gain-of-function mutation) and stat92E06346 (loss-of-function allele) were both shorter lived (p = 8.87×10−23; 2.92×10−53, respectively) than control, and flies heterozygous for hop3 (loss-of-function allele) had longer lifespan compared to control flies (p = 7.34×10−25). (C) Flies of indicated genotype and age were confined in food vials and their movements were recorded by video and then analyzed as average velocity. Each data point is the average of >3 recordings of different groups of flies. Error bars are S.E.M. Note that Su(var)205+/− flies lose mobility precipitously as they age, whereas hsp70-HP1 flies maintain high mobility for a longer period of time. (D) Top: adult large instestines of indicated age and genotype were stained with phalloidin-fluorescein to reveal the longitudinal and circular intestinal body wall muscle fibers. Images are partions of representative midgut showing 3 longitudinal fibers (wide bands) and circular fibers (thin bands). Note that Su(var)205+/− flies exhibit premature muscle degeneration: the longitudinal fibers are discontinuous with “loose ends”. Bottom: each fluorescein-stained gut was assigned a morphology score of 0 to 10 based on the integrity of the longitudinal muscle fibers (see Methods). The muscle integrity index was calculated by averaging the scores of 10 guts for each indicated genotype and age. Su(var)2055/+ and Su(var)2052/+ showed similar phenotypes; the results were combined. Error bars are standard deviations.
Figure 2.
Heterochromatin levels decline with aging.
(A) Gut tissues from young (3-day old) and old (35-day old) female flies were dissected and stained with anti-HP1 (magenta). Images were scanned at identical settings with confocal microscopy. Note that HP1 forms prominent foci in the young gut (one pointed by an arrow), whereas in the old gut HP1 staining seems more diffuse and lacks the prominent foci. (B) Male flies of indicated age (in weeks) were homogenized and the protein extracts were subjected to SDS-PAGE and blotted sequentially with antibodies for H3K9m2, HP1, H3, and α-Tubulin. Representative images for one of the three experiments are shown. Lower panels show intensity ratios as indicated. Note that total H3 levels decrease with age, and that H3K9m2 signals decrease with age even when normalized to total H3. (C) Chromatin immunoprecipitation (ChIP) was carried out with anti-HP1 antibodies using extracts from young (3-day old) and old (35-day old) male wild-type or hsp70-HP1/+ flies. Note that HP1 is enriched in 1360 (representative heterochromatin sequence) of young but not old wild-type flies (lane 2, top two panels), and is detectable in both young and old hsp70-HP1/+ flies (middle panels). (D) Ovaries from young (3-day old) and old (35-day old) female DX1 flies were stained with anti-ßgal. Note the much increased ßgal levels in old ovaries. (E) Total protein from single young (3-day old) and old (35-day old) female flies of indicated genotypes were blotted by anti-ß-gal antibodies or anti-aTublin (control). Note the appearance of ß-gal in old DX1 flies (arrow). The band below ß-gal is a nonspecific band.
Figure 3.
Heterochromatin affects stability of the nucleolus and rDNA locus.
(A) 3rd instar larval salivary glands of indicated genotypes were stained with anti-Fibrillarin. Stat92EF is a hypomorphic allele. Images were scanned with a confocal microscope at identical settings, and representative nuclei and quantifications are shown. N represents the number of nuclei scored. (B) 3rd instar larvae of indicated genotypes were processed for ECC (left) or genomic (right; control) DNA. The presence of indicated sequences were detected by PCR. Rp49 (lane 1) and 5S rDNA (lane 2) are non-repeated sequences and are used as negative controls for ECC. 1: rp49. 2: 5S rDNA. 3: Satellite 1.688. 4: 5′ 18S rDNA. 5: 3′ 18S rDNA. 6: 18 to 5.8S spacer. 7: 5.8S rDNA. 8: 28S rDNA. 9: Mid 28S rDNA. 10: 3′ 28S rDNA. Each genotype was analyzed three times; representative PCR results are shown. ECC levels were quantified by calculating the ECC index for each genotype (see Methods) and the results are shown (bottom). Error bars indicate S.E.M., and p values (Student's t-Test) indicate statistical significance of the differences compared with wild type. Note that ECC DNA (lane 3–10) was detected at high levels in Stat92E, Su(var)205, and hopTum-l heterozygotes, only minimally in wild-type controls, but not in hop loss-of-function heterozygotes.
Figure 4.
Heterochromatin controls rRNA transcription.
(A) Schematic representation of a pre-rRNA transcript, with an R2 element inserted into the 28S gene. Arrows above the 5′ETS region represent PCR primers used for qPCR analysis. (B) RNA was isolated from 3rd instar larvae of indicated genotypes and was subjected to Northern blotting with an R2 5′ antisense probe. Transcripts from the Adh gene were used as a loading control. Levels of the transcripts were quantified with a phospho-imager. The full-length (FL) R2 transcript is 3.6 kb. The lower bands are all degradation products, which appear soon after transcription [42]. A density plot is shown to the right with arbitrary units (a.u.). (C) The levels of pre-rRNA in 2-day-old male flies of indicated genotypes were measured by qRT-PCR. Relative pre-rRNA levels are shown with standard deviations. (D) Representative larvae of indicated genotypes. Su(var)205−/− were transheterozygous for Su(var)2052 and Su(var)2055. (E) Flies of indicated genotypes were outcrossed to minimize genetic background effects and were raised in parallel at 25°C with similar larval density. Top: Representative male flies of indicated genotypes. Bottom: The fly body weight was measured as the average of 10 2-day old male flies. Su(var)2052/+ and Su(var)2055/+ male flies had similar body weights, the results were combined and shown as Su(var)205+/−. Standard deviations and p values (compared with wild-type control; Student's t-Test) are shown.