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First published online August 2, 2004
doi: 10.1242/10.1242/dev.01268

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Ribosomal protein L24 defect in Belly spot and tail (Bst), a mouse Minute

¹ Department of Human Genetics, University of Michigan Medical School, Ann Arbor, MI 48109, USA
² Department of Internal Medicine, University of Michigan Medical School, Ann Arbor, MI 48109, USA

View larger version (40K): [in a new window]   Fig. 3. The Bst mutation. (A) Map of the Rpl24 gene showing the informative PCR, the 4 bp deletion within the intron 1 branchpoint, the first codons of the open reading frame, and the premature stop codon in Bst (red). (B) Sequence chromatograms comparing +/+ and Bst/+ PCR products. The exon 2 splice acceptor (arrowheads) and 4 bp Bst deletion (boxed) are indicated. (C) Allele-specific PCR assay used to distinguish Bst and wild-type Rpl24 alleles. The deletion is unique to the C57BLKS Bst/+ strain. (D) Bst causes abnormal Rpl24 splicing with retention of intron 1. RT-PCR was performed using the indicated primers. A common downstream primer (*) was end-labeled with 32P using T4 DNA kinase. Product A originates from correctly spliced Rpl24 transcripts, whereas A' and B indicate inclusion of intron 1. The relatively low abundance of product A' is due to PCR competition and nonsense-mediated decay. The low level of product B in the wild-type lanes most probably reflects amplification from hnRNA. (E) Some Bst transcripts are correctly spliced. RT-PCR was performed using (Bst/+ x SPRET) F1 RNA and the indicated primers. The upstream primer spans the exon 1-2 junction. Product C (388 bp) was end-labeled and digested with AluI to distinguish between musculus (M, 365 bp) and spretus (S, 135 bp) alleles. The molar ratio of M and S products is 1.27 for +/+ mice and 0.26 for Bst/+ littermates, giving a normalized expression level for Bst of 0.21 (±0.02). (F) Similar fluorometric assay performed using a HEX-labeled reverse primer and ABI sequencer following AluI digestion. The Bst expression level is 0.25 (±0.03) relative to wild-type musculus Rpl24. (G) Sequence of correctly spliced Rpl24 cDNAs amplified from F1 mice, showing the informative AluI site in exon 4 (overlined, sense strand). The normalized ratio of Bst to wild-type peak areas is 0.22 (±0.01).

View larger version (30K): [in a new window]   Fig. 4. Transgene correction of the Bst phenotype. (A) BAC clone RP23-10L10 (blue) contains Rpl24 and five other genes, and spans 181 kb (Ensembl mouse genome database, v. 12.3.1). (B) Founder Tg321 carries an intact RP23-10L10 transgene, which suppresses external Bst phenotypes in all doubly heterozygous offspring (compare mice 4514 and 4516 with 4515). Genotypes were determined using BAC end (red) and allele-specific Rpl24 PCRs. (C) Correction data summary. Four BAC transgenic founders were mated to C57BLKS Bst/+ mice. Tg321 and Tg326, which are intact, correct Bst phenotypes but Tg898 or Tg901, which lack Rpl24, do not. (D) Human RPL24 transgene (R26-huL24). The cDNA is ubiquitously expressed using the murine ROSA26 promoter.

View larger version (61K): [in a new window]   Fig. 1. C57BLKS Bst/+ phenotypes. (A) Kinked tail (arrowhead), white hind feet and belly spot. (B) Hematoxylin and eosin staining of +/+ and Bst/+ retinal sections. (C) Neurofilament (NF160) immunostaining of adjacent sections at the optic nerve head, marking ganglion and horizontal cells. (D) Skeletal stain of newborn fore limbs (upper) and hind limbs (lower), showing preaxial polydactyly (0) and triphalangy of the first digit (1) in Bst/+ limbs. (E) Postnatal growth curves of littermate +/+ and Bst/+ pups. (F) Weights (grams±s.e.m.) of adult +/+ and Bst/+ littermates, compared using a two-tailed unpaired t-test (n=44 total). Scale bars in B,C: 50 µm. ON, optic nerve head; ONL, outer nuclear layer; INL, inner nuclear layer; GCL, ganglion cell layer.

View larger version (26K): [in a new window]   Fig. 2. Positional cloning of Bst. (A) Recombination data localizing Bst to a 0.5 cM interval on mouse chromosome 16 (shaded in red) and excluding Opa1 and Hes1. Bst and microsatellite alleles transmitted by F1 parents are indicated together with the number of N2 progeny in each class. The 135 N2 mice typed with the extended marker set (left) are included in the total (right). , CAST/Ei; , C57BLKS. (B) Physical map of critical Bst region derived from Ensembl mouse genome database (3.35 Mb, v. 4.1.1). The map shows informative microsatellite markers, candidate transcription units and relevant BAC clones (blue). The nonrecombinant interval maps within cytogenetic band B4, spans 1.5 Mb (green arrows) and includes Rpl24 (red).

View larger version (38K): [in a new window]   Fig. 5. Bst impairs ribosome biogenesis. (A) Bst/+ causes a decrease in processed rRNAs. C57BLKS Bst/+ and +/+ littermates were fasted for 48 hours and re-fed for 2 hours. Tissue RNAs were radiolabeled by an intraperitoneal 32P injection at the start of the re-feeding period. (left) Autoradiogram of pulse-labeled liver RNA (5 µg/lane). Mature 18S and 28S rRNAs and 34S and 45S precursors are indicated. (center) Methylene Blue stain of the same filter, showing total RNA. (right) Density tracing of autoradiogram showing that Bst has a greater effect on 28S rRNA. The Bst/+ profile is scaled twofold to equalize 18S rRNA levels. The relative peak areas measured for 45S, 34S, 28S and 18S rRNAs are 0.9, 1.1, 5.9 and 4.2 (+/+) and 0.9, 1.1, 1.5 and 1.8 (Bst/+), respectively. (B) Sucrose gradients of liver homogenates from normally fed +/+ and Bst/+ adult littermates. UV absorbance peaks corresponding to ribosomal subunits and polysomes are labeled. A prominent shoulder is present between the 60S and 80S subunits (arrowhead).

View larger version (30K): [in a new window]   Fig. 6. Cellular effects of the Bst mutation. (A) Protein synthesis ([3H]leu incorporation) is decreased in Bst/+ MEFs (P<0.001, two-tailed unpaired t-test). (B) Growth rates of subconfluent +/+ and Bst/+ MEF cultures (cell counts), showing decreased doubling time of Bst/+ cells (P<0.001, two-tailed unpaired t-test). (C) Bivariate cell cycle analysis. Cells were sorted by total DNA content (7-AAD fluorescence) and BrdU incorporation (FITC-conjugated antibody). Density plots represent combined data from two experiments (20,000 cells each). The histogram shows the proportion of cells in G1, S and G2/M sectors (red boxes); bars indicate the range for two experiments. The distribution of cells in G1, S and G2/M differ significantly between Bst/+ and +/+ (P<0.001, 2=233 for 2x3 contingency table). (D) S-phase entry of Bst/+ MEFs is delayed following 48 hour serum starvation. [3H]thymidine incorporation was normalized for each genotype to the highest level measured during the experiment. The panel shows one of three independent experiments performed. Each point shows the average of three cultures; bars indicate standard deviation. (E) Model for increased cell cycle length, based on bivariate FACS analysis and doubling times. Assuming the length of S phase is constant, Bst/+ MEFs remain significantly longer in G1 before reaching the restriction point (R).

View larger version (92K): [in a new window]   Fig. 7. Bst causes a growth disadvantage in vivo. (A) Chimera analysis protocol. Exactly five or ten R26 ES cells were injected into mutant and control blastocysts. (B) Coat color comparison of adult chimeras. Rpl24 genotypes were determined by allele-specific PCR. C57BLKS and R26 contributions were determined by the percent black (a/a) and agouti (A/A) coloration, respectively. The R26 contribution was significantly greater in chimeras derived from Bst/+ blastocysts, in experiments where five (left) or ten (right) ES cells were injected (P<0.01, Mann-Whitney nonparametric rank sum tests). Open and closed symbols represent female and male chimeras, respectively. (C) Typical Bst/+ and +/+ chimeras showing 50% and 5% agouti coats, respectively (ten ES cell injection). (D) ß-Galactosidase staining of cryopreserved tissues from chimeras in (C). The increased R26 contribution (lacZ positive) in Bst/+ chimeras is evident in all tissues examined. Scale bars: 150 µm.