Ytm1, Nop7, and Erb1 Form a Complex Necessary for Maturation of Yeast 66S Preribosomes

Pre-rRNA processing and pre-rRNP maturation pathway in Saccharomyces cerevisiae. (A) The 35S pre-rRNA contains sequences for mature 18S, 5.8S, and 25S rRNAs (represented as thick horizontal lines) along with additional internal and external spacer sequences (represented as thin horizontal lines). The 35S pre-rRNA is transcribed by RNA polymerase I and rapidly modified and processed to produce 33S pre-rRNA. Cleavage of 33S pre-rRNA at site A₀ generates 32S pre-rRNA. The 20S and 27SA₂ pre-rRNA processing intermediates are generated through internal cleavage of 32S pre-rRNA at the A₂ site. Subsequent processing and cleavage of 20S and 27SA₂ pre-rRNAs result in the production of the mature 18S, 25S, and 5.8 rRNAs, respectively. 5S rRNA is transcribed separately by RNA polymerase III. (B) Pre-rRNA processing occurs in preribosomal particles. The 35S primary transcript is found within the 90S pre-rRNP (dark gray circle). Cleavage at site A₂ initiates subunit-specific maturation, generating the 43S and 66S pre-rRNPs (light gray circles). The 43S preribosome is exported to the cytoplasm, where final steps in 20S maturation take place. Multiple 66S preribosomes exist that contain each of the 27S or 25.5S plus 7S pre-rRNA processing intermediates. The mature 40S subunit contains 18S rRNA, whereas the 60S subunit contains 25S, 5.8S, and 5S rRNA (white circles).

Ytm1 is a WD40 repeat-containing protein. (A) Predicted amino acid sequence of S. cerevisiae Ytm1. WD40 repeats are overlined. Amino acid residues altered in the ytm1-1 mutant are indicated by asterisks. (B) Ras Mol 2.6 was used to generate the top and side view of a model for amino acids 103 to 450 of Ytm1, based on the crystal structure of the WD repeat protein Gβ.

The ytm1-1 mutant is deficient in 60S ribosomal subunits. Free 40S and 60S ribosomal subunits, monoribosomes, and polyribosomes were assayed in yeast strains JWY3400 (YTM1) (left) or JWY7128 (ytm1-1) (center) grown at 25°C or JWY7128 grown at 25°C and shifted to 37°C for 3 h (right). Whole-cell extracts prepared from each strain were fractionated on 7 to 47% sucrose gradients. A ₂₆₀ peaks representing 40S and 60S ribosomal subunits and 80S monosomes are labeled. Half-mer polyribosomes are indicated by vertical arrows.

Inactivation of Ytm1 in the ytm1-1 mutant causes 66S preribosomes to accumulate in the nucleolus. The ytm1-1 mutant strain JWY6790 expressing eGFP-tagged rpL25 was grown in C-Trp medium at 25°C, washed and suspended in YEPD, and grown at 25°C (A and C) or shifted to 37°C for 5 h (B and D). Nuclei stained with 4′,6′-diamidino-2-phenylindole (DAPI) are shown in panels A and B (typically, nucleoli do not stain with DAPI). The signal from RpL25eGFP is shown in panels C and D. Arrows indicate nucleolar accumulation of rpL25eGFP (D) and corresponding DAPI staining (B).

Ytm1-HA3 cosediments on sucrose gradients with 66S preribosomes. Whole-cell extracts were prepared from yeast strain JWY6770 (YTM1-HA3) and fractionated on 7 to 47% sucrose velocity gradients. Fractions containing 40S and 60S ribosomal subunits and 80S monosomes are labeled. Proteins were trichloroacetic acid precipitated from gradient fractions and subjected to Western immunoblot analysis to detect Ytm1-HA3.

Ytm1 associates with pre-rRNAs in 66S preribosomes. (A) Whole-cell extracts were prepared from the YTM1-TAP strain JWY7124 and from untagged strain JWY3400 grown at 30°C in YEPD medium to 6× 10⁷ cells/ml. RNA was extracted from whole cells and from tandem affinity-purified samples, subjected to electrophoresis on agarose-formaldehyde or acrylamide-urea gels, blotted to nitrocellulose, and assayed by Northern blotting with specific oligonucleotide probes complementary to pre-rRNAs and mature rRNAs. Five percent of total RNA and 100% of tandem affinity-purified RNA were assayed. (B) Primer extension analysis was used to assay 35S, 27SA₂, 27SA₃, and 25.5S pre-rRNAs, as well as the B_S and B_L 5′ ends of 27S and 7S pre-rRNAs, using ³²P-labeled oligonucleotides. Products of primer extension were resolved on sequencing gels, dried, and exposed to X-ray film for detection by autoradiography. (C) 35S pre-rRNA copurifies with TAP-tagged Erb1 and Nop7 but not Ytm1. RNA in whole-cell extracts and copurifying RNAs were assayed by primer extension as described above.

Nonribosomal proteins necessary for biogenesis of 60S ribosomal subunits, as well as ribosomal proteins, copurify with TAP-tagged Ytm1. Whole-cell extract was prepared from the YTM1-TAP strain JWY7124 grown at 30°C in YEPD medium to 6 × 10⁷ cells/ml and subjected to tandem affinity purification. Proteins were trichloroacetic acid precipitated from column eluates and subjected to electrophoresis on 4 to 20% polyacrylamide gels. Proteins were stained with colloidal Coomassie blue, manually excised from the gel, digested with trypsin, and identified by matrix-assisted laser desorption ionization-time of flight mass spectrometry (Table 2).

Ytm1, Erb1, and Nop7 form a heterotrimeric subcomplex both within 66S preribosomes and independently of these particles. (A) Ytm1, Erb1, and Nop7 are enriched (relative to other proteins found in 66S pre-rRNPs) among proteins copurifying with Ytm1-TAP or Nop7-TAP from rrp1-1 or nop4-3 mutants in which 66S preribosomes are unstable. Heterotrimer was purified (B) from sucrose gradient fractions, (C) by differential centrifugation, or (D) from whole-cell extracts treated with a cocktail of phosphatase inhibitors that disrupt 66S pre-rRNPs. Wild-type cells or mutant cells were grown at 25°C and shifted to 37°C for 5 h. Tandem affinity purification using Nop7-TAP or Ytm1-TAP was carried out from (A) whole-cell extracts from a 50-ml culture, (B) gradient fractions 5 to 7 (prepared from a 900-ml culture), (C) whole-cell extracts from 50 ml of cells (lanes 1 and 3) or 180,000 × g spin supernatants prepared from 500 ml of cells (lanes 2 and 4), or (D) untreated (−) or phosphatase inhibitor cocktail-treated extracts (+). Purified proteins were resolved by SDS-PAGE. Note that the heterotrimer is destabilized in the ytm1-1 mutant (B, lane 2; C, lane 4; D, lane 4). (E) Ytm1, Erb1, and Nop7 form a stable subcomplex within 66S preribosomes. Whole-cell extracts from YTM1 cells were subjected to centrifugation on 7 to 47% gradients. Fractions containing 66S preribosomes were pooled and subjected to tandem affinity purification in the presence (+) or absence (−) of phosphatase inhibitors, and proteins were resolved by SDS-PAGE. Bands indicated by asterisks in B and E are common contaminants that we observe upon TAP from any fractions of sucrose gradients (top, middle, or bottom) using any TAP-tagged protein.

Ytm1 and Nop7 directly interact with Erb1. (A) Synthetic radiolabeled proteins (*) were incubated with GST fusion proteins (lanes 2, 5, and 8). As negative controls, synthetic peptides were incubated with GST beads only (lanes 1, 4, and 7) or GST fusion proteins were incubated with the unrelated, radiolabeled 40S ribosome assembly factor Krr1 or ribosomal protein L11 (lanes 3, 6, and 9). (B) Radiolabeled wild-type Ytm1 protein was preincubated at 37°C for 15 min (lane 2). Mutant Ytm1-1 protein was preincubated at 37°C for 15 min (lane 3), 30 min (lane 4), or 60 min (lane 5). Following preincubation, wild-type Ytm1 or mutant Ytm1-1 radiolabeled protein was incubated with GST-Erb1. Mutant Ytm1-1 protein was incubated with GST beads only (lane 1) as a negative control. Complexes were eluted from glutathione beads, subjected to electrophoresis on 10% polyacrylamide gels, and detected by autoradiography. (C) Model for interactions between Ytm1, Erb1, and Nop7. Gray lines indicate interactions detected using GST pulldown assays, whereas the black line indicates interactions detected by two-hybrid assays.