Ribosomal protein gene sequences map to human chromosomes 5, 8, and 17

Deletion 5q MDS: molecular and therapeutic implications

Heterozygous, interstitial deletions of chromosome 5q are the most common cytogenetic abnormality in myelodysplastic syndromes (MDS). This chromosomal abnormality is associated with a consistent clinical phenotype, the 5q- syndrome, in a subset of patients, and therapeutic sensitivity to the drug lenalidomide. No genes on chromosome 5q undergo recurrent homozygous inactivation in MDS patients. Instead, haploinsufficiency for key genes powerfully alters hematopoiesis, leading to the MDS phenotype in patients with del(5q). Haploinsufficiency for the RPS14 gene leads to activation of the p53 pathway and the macrocytic anemia characteristic of this disorder, and loss of p53 rescues erythropoiesis and facilitates clonal progression. Other genes, as well as miR-145 and miR-146a, contribute to aberrant megakaryopoiesis and a selective advantage for the del(5q) clone. The integrated effects of haploinsufficiency for these key genes, in aggregate, lead to the full phenotype of the disorder.

Biology and treatment of the 5q- syndrome

The 5q- syndrome is a unique subtype of myelodysplastic syndromes typified by a relatively indolent course and responsiveness to lenalidomide. Here, we review the salient biologic features of this disease. Hemizygous deletion of a segment of chromosome 5q is believed to be the disease-initiating event. Recent molecular techniques have isolated the common deleted region and characterized key candidate genes contributing to the disease phenotype. Gene-specific RNA interference strategies revealed that haplo-insufficiency for the RPS14 gene, which encodes a ribosomal protein, is a critical effector of the p53-dependent erythroid hypoplasia and apoptotic loss of erythroid precursors. Disease-specific sensitivity to lenalidomide results from the drug's inhibitory effect on two haplodeficient phosphatases, PP2Acα and CDC25c, which are coregulators of the G(2)/M checkpoint. Hyperphosphorylation of MDM2, as a result of inhibition of PP2A phosphatase activity, stabilizes MDM2, permitting p53 degradation and transition to G(2) arrest and clonal suppression. With the emerging data elucidating the pathogenesis of the 5q- syndrome and the success of clinical trials, a cohesive story connecting the biology and pharmacology associated with this subtype of myelodysplastic syndromes has emerged.

Mapping of the human ribosomal large subunit protein gene RPL29 to human chromosome 3q29-qter

The human ribosomal protein L29, which we reported previously, was subsequently shown to have the same nucleotide sequence as that of cell surface heparin/heparan sulfate-binding protein, designated HP/HS interacting protein. A polymerase chain reaction-based strategy was used to distinguish the functional intron-containing gene RPL29 (HGMW-approved symbol) from multiple pseudogenes. By somatic cell hybrid analysis, radiation hybrid mapping, and fluorescence in situ hybridization, we have located RPL29 on the telomeric region of the q arm of chromosome 3. RPL29 is the most distal marker of the long armof chromosome 3. Of the human ribosomal protein genes mapped, RPL29 is the shortest distance from another ribosomal protein gene marker, RPL35 a which has also been mapped to the 3q29-qter region.

Functional analysis of human RPS14 null alleles

Previously we described a large collection of cloned human DNAs that encode chemically defined missense mutations within the ribosomal protein S14 sequence. We determined that biologically inactive (i.e. null) alleles resulted primarily from point mutations targeted to two internal segments of the S14-coding sequence and designated these functionally critical regions as domains B and D. Further, we inferred that structural determinants within domains B and D are required for proper incorporation of the S14 protein into nascent 40 S ribosomal particles and/or for the normal function of mature cytoplasmic ribosomes. In this study we have used immunofluorescence to monitor the intracellular trafficking of epitopically labeled human S14 protein isoforms transiently expressed by cultured Chinese hamster cells. Data obtained distinguish null alleles of RPS14 which encode proteins that are not incorporated into pre-ribosomal subunit particles from null alleles whose products are compatible with normal ribosome assembly processes but result in functionally inactive cytoplasmic 40 S ribosomal subunits. Mutations assigned to the first allele class involve amino acid replacements located within S14 domains B and D; whereas mutations assigned to the second class are distributed throughout the S14 protein-coding sequence.

The intron-containing ribosomal protein-encoding genes L5, L7a and L37a are unlinked in chicken

Chicken ribosomal protein (rp)-encoding genes are currently being studied at the nucleotide level and three independent recombinant phages have been isolated from chicken genomic libraries using cloned cDNA probes. Each of these was shown to include an intron-containing rp gene of chicken (L5, L7a, L37a). In this study the chromosomal location of these three intron-containing rp from the large subunit of the chicken ribosome was determined by fluorescence in situ hybridization. L7a mapped to a microchromosome, whereas L5 and L37a mapped to macrochromosomes 8 and 7, respectively. The results demonstrate that these functionally related genes are widely dispersed in the genome. Furthermore, as in the case of many other evolutionarily advanced eukaryotes, there is no apparent linkage of rp and rRNA genes.

A densely methylated DNA island is associated with a chromosomal replication origin in the human RPS14 locus

We describe a 258-bp densely methylated DNA island (DMI) and chromosomal origin of bidirectional DNA replication within the transcribed portion of the human RPS14 intron 1. Together with the DMIs previously detected in two functional Chinese hamster replication origins [see Ref. 1, pp. 5636-5644], observations described in this report strengthen the correlation between densely methylated DNA islands and active mammalian chromosomal replication origins. Accordingly, DMIs may prove to be reliable physical markers for origins of bidirectional DNA replication in complex genomic DNAs of higher animals.

Identification and genetic mapping of 151 dispersed members of 16 ribosomal protein multigene families in the mouse

More than 150 individual members of 16 ribosomal protein multigene families were identified as DNA restriction fragments and genetically mapped. The ribosomal protein gene-related sequences are widely dispersed throughout the mouse genome. Map positions were determined by analysis of 144 progeny mice from both an interspecific (C57BL/6J x SPRET/Ei)F1 x SPRET/Ei and an intersubspecific (C57BL/6J x CAST/Ei)F1 x C57BL/6J backcross. In addition, 30 members of the multigene families encoding PGK1 ODC, and TPI, including five new loci for ODC and one new locus for TPI, were characterized and mapped. Interspecific backcross linkage data for 29 nonecotropic murine leukemia retroviruses endogenous to C57BL/6J mice are also reported. Transmission ratio distortions and recombination frequencies are compared between the two backcrosses.

Densely methylated DNA islands in mammalian chromosomal replication origins

Densely methylated DNA sequence islands, designated DMIs, have been observed in two Chinese hamster cell chromosomal replication origins by using a PCR-based chemical method of detection. One of the origins, oriS14, is located within or adjacent to the coding sequence for ribosomal protein S14 on chromosome 2q, and the other, ori-beta, is approximately 17 kbp downstream of the dhfr (dihydrofolic acid reductase) locus on chromosome 2p. The DMI in oriS14 is 127 bp long, and the DMI in ori-beta is 516 bp long. Both DMIs are bilaterally methylated (i.e., all dCs are modified to 5-methyl dC) only in cells that are replicating their DNA. When cell growth and DNA replication are arrested, methylation of CpA, CpT, and CpC dinucleotides is lost and the sequence islands display only a subset of their originally methylated CpG dinucleotides. Several possible roles for DMI-mediated regulation of mammalian chromosomal origins are considered.

Densely methylated DNA islands in mammalian chromosomal replication origins

Densely methylated DNA sequence islands, designated DMIs, have been observed in two Chinese hamster cell chromosomal replication origins by using a PCR-based chemical method of detection. One of the origins, oriS14, is located within or adjacent to the coding sequence for ribosomal protein S14 on chromosome 2q, and the other, ori-beta, is approximately 17 kbp downstream of the dhfr (dihydrofolic acid reductase) locus on chromosome 2p. The DMI in oriS14 is 127 bp long, and the DMI in ori-beta is 516 bp long. Both DMIs are bilaterally methylated (i.e., all dCs are modified to 5-methyl dC) only in cells that are replicating their DNA. When cell growth and DNA replication are arrested, methylation of CpA, CpT, and CpC dinucleotides is lost and the sequence islands display only a subset of their originally methylated CpG dinucleotides. Several possible roles for DMI-mediated regulation of mammalian chromosomal origins are considered.

Deoxycytidine methylation and the origin of spontaneous transition mutations in mammalian cells

Previously we described a recurrent, site-specific G4784 --> A transition mutation affecting exon V of the Chinese hamster ovary cell RPS14 gene. Because the mutation is located within a CpG dinucleotide, we considered the possibility that deoxycytidine methylation might be responsible for the transition's unusually high frequency and site specificity. Therefore, we used a procedure based on the PCR amplification of bisulfite-modified genomic DNA to analyze the pattern of DNA cytosine methylation in exon V of the CHO cell RPS14 locus. Our data indicate that the CpG dinucleotide targeted by the transition mutation is stably methylated in CHO cell chromosomes. This finding supports the notion that deoxycytidine methylation promotes "spontaneous", site-specific transition mutations in mammalian cells.

A multipoint genetic linkage map of mouse chromosome 18

We have mapped 13 loci on mouse Chromosome 18 by Southern blot analysis of restriction fragment length polymorphisms among progeny from an interspecific backcross: (C57BL/6J X Mus spretus) X M. spretus. Complete haplotype analysis of 136 of these progeny was used to establish gene order and estimate genetic distances between loci. The gene order (from centromere to telomere) and recombination distances (in centimorgans) were as follows: PGK-1rs5-4.3-Tpi-10-11.8-(Egr-1, Hmg17-rs9)-2.1-Fgfa-2.2-Grl-1-10.1-(Cdx-1, Csfmr, Pdgfrb, Pdea, Rps14)-2.1-Adrb-2-22.9-Mbp. Pgk-1rs5, Tpi-10, Hmg17-rs9, and Rps14 had not been previously mapped in the mouse; Egr-1 had only been syntenically assigned to mouse Chr 18. Nine of the loci, spanning 18 cM, have homologs on the distal long arm of human Chr5--a region rich in genes encoding growth factors and receptors. An additional previously unmapped gene, Drd-1, predicted to be on mouse Chr 18 based on its human chromosomal location, was mapped to the middle region of mouse Chr 13.

Identification of a putative gamma-aminobutyric acid (GABA) receptor subunit rho2 cDNA and colocalization of the genes encoding rho2 (GABRR2) and rho1 (GABRR1) to human chromosome 6q14-q21 and mouse chromosome 4

Screening of a genomic DNA library with a portion of the cDNA encoding the gamma-aminobutyric acid (GABA) receptor subunit rho1 identified two distinct clones. DNA sequencing revealed that one clone contained a single exon from the rho1 gene (GABBR1) while the second clone encompassed an exon with 96% identity to the rho1 gene. Screening of a human retina cDNA library with oligonucleotides specific for the exon in the second clone identified a 3-kb cDNA with an open reading frame of 1395 bp. The predicted amino acid sequence of this cDNA demonstrates 30 to 38% similarity to alpha, beta, gamma, and delta GABA receptor subunits and 74% similarity to the GABA rho1 subunit suggesting that the newly isolated cDNA encodes a new member of the rho subunit family, tentatively named GABA rho2. Polymerase chain reaction (PCR) amplification of rho1 and rho2 gene sequences from DNA of three somatic cell hybrid panels maps both genes to human chromosome 6, bands q14 to q21. Tight linkage was also demonstrated between restriction fragment length variants (RFLVs) from each rho gene and the Tsha locus on mouse chromosome 4, which is homologous to the CGA locus on human chromosome 6q12-q21. These two lines of evidence confirm that GABRR1 and newly identified GABRR2 map to the same region on human chromosome 6. This close physical association and high degree of sequence similarity raises the possibility that one rho gene arose from the other by duplication.

Sixty-five radiation hybrids for the short arm of human chromosome 6: their value as a mapping panel and as a source for rapid isolation of new probes using repeat element-mediated PCR

We have used an irradiation and fusion procedure to generate somatic cell hybrids that retain fragments of the short arm of human chromosome 6 (6p). To identify hybrids retaining human material, we performed repeat element-mediated PCR on crude lysates of cells from individual clones. Sixty-five hybrids were shown to contain human material and fifty of those contained one or more 6p-specific probes. Detailed characterization of these hybrids identified a subset that divides 6p into ten mapping intervals. Using repeat element-mediated PCR, we were able to isolate and map 61 new DNA fragments from specific regions of 6p. Fifteen of these fragments were used to screen for restriction fragment length polymorphisms (RFLPs), and nine identified RFLPs with one or more enzymes. The radiation hybrids described in this study provide a valuable resource for high-resolution mapping of 6p and for the rapid isolation of region-specific markers.

"PCR-karyotype" of human chromosomes in somatic cell hybrids

Amplification of human DNA sequences in 16 monochromosomal somatic cell hybrids containing different human chromosomes were performed by the polymerase chain reaction (PCR) using primer directed at human-specific regions of Alu or L1, the two major classes of interspersed repetitive sequences (IRS-PCR). A chromosome-specific pattern of amplification products was observed on agarose gels run with ethidium bromide, producing a "PCR-karyotype." This simple gel analysis provides a rapid method for identifying and monitoring the human chromosomal content of monochromosomal somatic cell hybrids without conventional cytogenetic analysis. Hybrids containing multiple human chromosome produce complex gel patterns, but identification of chromosome content can be achieved by hybridization of PCR products against a reference panel of monochromosomal or highly reduced hybrids representing each human chromosome. This dot-blot method also enables identification of human marker chromosomes or translocated pieces in hybrids that are not identifiable by cytogenetic methods. These IRS-PCR methods should greatly reduce the need for more laborious cytogenetic, isozyme, and Southern blot characterizations of human-rodent cell hybrids.

Genetic analysis of a vital mammalian housekeeping locus using CHO cells that express a transfected mutant allele

We describe a novel approach for the isolation of null mutations in a vital Chinese hamster ovary (CHO) cell housekeeping gene. Our experimental strategy required introduction of an expressible DNA clone encoding a recessive emetine-resistance allele of ribosomal protein S14 into wild-type CHO cells. Transgene heterozygote (TGH) cell lines, which harbor multiple emetine-resistance S14 transgenes, survive mutations that inactivate the CHO RPS14 locus by virtue of the transgenes' biological function. Null mutations in RPS14 yield TGH clones that display the transgene's drug-resistance phenotype. A large collection of emetine-resistant clones was isolated from one TGH cell line and shown to consist of three types of S14 mutations: (1) nonsense null mutations in the RPS14 protein coding sequence; (2) missense null mutations that affect S14 amino acid residues that have been conserved stringently during eukaryotic evolution; and (3) a recurrent missense mutation that results in a new, functional RPS14 emetine-resistance allele.

Complete amino acid sequence of human cartilage link protein (CRTL1) deduced from cDNA clones and chromosomal assignment of the gene

Little is known about the primary amino acid structure of human cartilage link protein (CRTL1). We screened a human genomic library with a cDNA encoding the 3' untranslated region and the adjoining B1 domain of chicken link protein. One clone was isolated and characterized. A 3.5-kb EcoRI-KpnI fragment from this genomic clone that contains the human B1 exon was used to map the gene to chromosome 5q13----q14.1. The same fragment was used to screen a cDNA library prepared from mRNA of Caco-2, a human colon tumor cell line. Two overlapping clones were isolated and shown to encode all of CRTL1. The deduced amino acid sequence is 354 residues long. The amino acid sequence shows a striking degree of identity to the porcine (96%), rat (96%), and chicken (85%) link protein sequences. Furthermore, there is greater than 86% homology between the 3' untranslated region of the genes encoding human and porcine link proteins. These results indicate that there has been strong evolutionary pressure against changes in the coding and 3' untranslated regions of the gene encoding cartilage link protein.

A Drosophila ribosomal protein functions in mammalian cells

A cDNA expression vector encoding Drosophila ribosomal protein S14 was transfected into cultured Chinese hamster ovary (CHO) cells that harbor a recessive RPS14 emetine resistance mutation. Transformants synthesized the insect mRNA and polypeptide and consequently displayed an emetine-sensitive phenotype. These observations indicate that the insect protein was accurately expressed and correctly assembled into functional mammalian 40S ribosomal subunits.

A Drosophila ribosomal protein functions in mammalian cells

A cDNA expression vector encoding Drosophila ribosomal protein S14 was transfected into cultured Chinese hamster ovary (CHO) cells that harbor a recessive RPS14 emetine resistance mutation. Transformants synthesized the insect mRNA and polypeptide and consequently displayed an emetine-sensitive phenotype. These observations indicate that the insect protein was accurately expressed and correctly assembled into functional mammalian 40S ribosomal subunits.

Human chromosome 12 is required for elevated HIV-1 expression in human-hamster hybrid cells

Host cell factors act together with regulatory genes of the human immunodeficiency virus (HIV) to control virus production. Human-Chinese hamster ovary hybrid cell clones were used to probe for human chromosomes involved in regulating HIV gene expression. DNA transfection experiments showed that 4 of 18 clones had high levels of HIV gene expression measured by both extracellular virus production and transactivation of the HIV long terminal repeat in the presence of the trans-activator (tat) gene. Karyotype analyses revealed a 94% concordance (17/18) between human chromosome 12 and HIV gene expression. Other chromosomes had an 11 to 72% concordance with virus production.

Localization of the Surfeit gene cluster containing the ribosomal protein gene L7a to chromosome bands 9q33-34

The Surfeit gene cluster which contains at least four very tightly spaced unrelated genes, one of which encodes the ribosomal protein L7a, has been localized by an analysis of somatic cell hybrids to the long arm of chromosome 9. By the use of in situ hybridization the Surfeit locus has been further mapped to 9q33-34.

The transcriptionally active human ribosomal protein S17 gene

A human ribosomal protein S17 cDNA [Chen et al., Proc. Natl. Acad. Sci. USA 83 (1986) 6907-6911] was used to isolate four S17 DNA clones from human genomic libraries constructed in bacteriophage lambda and cosmid vectors. Based on its transcriptional activity in a transient expression assay and on sequence similarity with S17 cDNA, cosmid clone HGS17-6 was identified as carrying the functional RPS17 gene. RPS17 is composed of five exons and four introns that span 4 kb of DNA. Two lambda clones of human genomic DNA were recognized as containing processed S17 pseudogenes, because (i) they were transcriptionally inactive in the transient assay, and (ii) they possess multiple, perfectly spliced RPS17 exons. Their coding sequences differ slightly from the cDNA and functional genomic clone.

Isolation and characterization of cloned cDNAs that code for human ribosomal protein S6

Ribosomal protein (rp) S6 is the major substrate of protein kinases in eukaryotic ribosomes. To facilitate the identification of cloned cDNAs for human rpS6, we used published amino acid (aa) sequence data for rat liver rpS6 and yeast (Saccharomyces carlsbergensis) rpS10 to design mixed oligodeoxynucleotide probes. Screening of several human cDNA libraries with these probes permitted the isolation of plasmids which encompass the entire coding sequence of rpS6 (249 aa residues), 27 bp of the 5'-untranslated leader and all 39 bp of the 3'-untranslated region. A comparison of the predicted human rpS6 amino acid sequence and the yeast rpS10 amino acid sequence shows highly conserved areas separated by regions of divergence.

A cloned human ribosomal protein gene functions in rodent cells

Cloned fragments of human ribosomal protein S14 DNA (RPS14) were transfected into cultured Chinese hamster (CHO) cells. Transient expression assays indicated that DNA with as little as 31 base pairs of upstream flanking sequence was transcribed into a polyadenylated, 650-base mRNA that is largely bound to the polyribosomes. In these respects the exogenous human S14 message appeared to function normally in CHO cells. Interestingly, transcription of human RPS14 did not require the TATA sequence located 26 base pairs upstream of exon 1. Stably transformed clones were selected from cultures of emetine-resistant CHO cells (Emr-2) after transfection with pSV2Neo-human RPS14 constructs. Human RPS14 complemented the mutationally based drug resistance of the Chinese hamster cells, demonstrating that the cloned human ribosomal protein gene is functional in rodent cells. Analysis of transformed cells with different amounts of integrated RPS14 indicated that human S14 mRNA levels are not tightly regulated by CHO cells. In contrast, the steady-state S14 level fluctuated only slightly, if at all, in transformed clones whose S14 message contents differed by more than 30-fold. These data support the conclusion that expression of human RPS14 is regulated, at least partially, posttranscriptionally.

A cloned human ribosomal protein gene functions in rodent cells

Cloned fragments of human ribosomal protein S14 DNA (RPS14) were transfected into cultured Chinese hamster (CHO) cells. Transient expression assays indicated that DNA with as little as 31 base pairs of upstream flanking sequence was transcribed into a polyadenylated, 650-base mRNA that is largely bound to the polyribosomes. In these respects the exogenous human S14 message appeared to function normally in CHO cells. Interestingly, transcription of human RPS14 did not require the TATA sequence located 26 base pairs upstream of exon 1. Stably transformed clones were selected from cultures of emetine-resistant CHO cells (Emr-2) after transfection with pSV2Neo-human RPS14 constructs. Human RPS14 complemented the mutationally based drug resistance of the Chinese hamster cells, demonstrating that the cloned human ribosomal protein gene is functional in rodent cells. Analysis of transformed cells with different amounts of integrated RPS14 indicated that human S14 mRNA levels are not tightly regulated by CHO cells. In contrast, the steady-state S14 level fluctuated only slightly, if at all, in transformed clones whose S14 message contents differed by more than 30-fold. These data support the conclusion that expression of human RPS14 is regulated, at least partially, posttranscriptionally.

Primary structure of human ribosomal protein S14 and the gene that encodes it

Chinese hamster ribosomal protein S14 cDNA was used to recognize homologous human cDNA and genomic clones. Human and Chinese hamster S14 protein sequences deduced from the cDNAs are identical. Two overlapping human genomic S14 DNA clones were isolated from a Charon 28 placental DNA library. A fragment of single-copy DNA derived from an intron region of one clone was mapped to the functional RPS14 locus on human chromosome 5q by using a panel of human X Chinese hamster hybrid cell DNAs. The human S14 gene consists of five exons and four introns spanning 5.9 kilobase pairs of DNA. Polyadenylated S14 transcripts purified from HeLa cell cytoplasma display heterogeneous 5' ends that map within noncoding RPS14 exon 1. This precludes assignment of a unique 5' boundary of RPS14 transcripts with respect to the cloned human genomic DNA. Apparently HeLa cells either initiate transcription at multiple sites within RPS14 exon 1, or capped 5' oligonucleotides are removed from most S14 mRNAs posttranscription. In contrast to the few murine ribosomal protein and several other mammalian housekeeping genes whose structures are known, human RPS14 contains a TATA sequence (TATACTT) upstream from exon 1. Three related short sequence motifs, also observed in murine and yeast ribosomal protein genes, occur in this region of the RPS14 gene. RPS14 introns 3 and 4 both contain Alu sequences. Interestingly, the Alu sequence in intron 3 is located slightly downstream from a chromosome 5 deletion breakpoint in one human X hamster hybrid clone analyzed.

Homologous ribosomal proteins in bacteria, yeast, and humans

We describe sequences of two human ribosomal proteins, S14 and S17, and messenger RNAs that encode them. cDNAs were used as molecular hybridization probes to recognize complementary genes in rodent, Drosophila, and yeast chromosomal DNAs. Human ribosomal protein sequences are compared to analogous Chinese hamster, yeast, and bacterial genes. Our observations suggest that some ribosomal protein genes have been conserved stringently in the several phylogenetic lines examined. These genes apparently were established early in evolution and encode products that are fundamental to the translational apparatus. Other ribosomal protein genes examined, although similar enough to heterologous DNA sequences to indicate their structural relationships, appear to have diverged substantially during evolution, probably reflecting adaptations to different genetic environments.

Primary structure of human ribosomal protein S14 and the gene that encodes it

Chinese hamster ribosomal protein S14 cDNA was used to recognize homologous human cDNA and genomic clones. Human and Chinese hamster S14 protein sequences deduced from the cDNAs are identical. Two overlapping human genomic S14 DNA clones were isolated from a Charon 28 placental DNA library. A fragment of single-copy DNA derived from an intron region of one clone was mapped to the functional RPS14 locus on human chromosome 5q by using a panel of human X Chinese hamster hybrid cell DNAs. The human S14 gene consists of five exons and four introns spanning 5.9 kilobase pairs of DNA. Polyadenylated S14 transcripts purified from HeLa cell cytoplasma display heterogeneous 5' ends that map within noncoding RPS14 exon 1. This precludes assignment of a unique 5' boundary of RPS14 transcripts with respect to the cloned human genomic DNA. Apparently HeLa cells either initiate transcription at multiple sites within RPS14 exon 1, or capped 5' oligonucleotides are removed from most S14 mRNAs posttranscription. In contrast to the few murine ribosomal protein and several other mammalian housekeeping genes whose structures are known, human RPS14 contains a TATA sequence (TATACTT) upstream from exon 1. Three related short sequence motifs, also observed in murine and yeast ribosomal protein genes, occur in this region of the RPS14 gene. RPS14 introns 3 and 4 both contain Alu sequences. Interestingly, the Alu sequence in intron 3 is located slightly downstream from a chromosome 5 deletion breakpoint in one human X hamster hybrid clone analyzed.