The human ribosomal protein S6 gene: isolation, primary structure and location in chromosome 9

S6K is a morphogenic protein with a mechanism involving Filamin-A phosphorylation and phosphatidic acid binding

Change of cell shape in vivo plays many roles that are central to life itself, such as embryonic development, inflammation, wound healing, and pathologic processes such as cancer metastasis. Nonetheless, the spatiotemporal mechanisms that control the concerted regulation of cell shape remain understudied. Here, we show that ribosomal S6K, which is normally considered a protein involved in protein translation, is a morphogenic protein. Its presence in cells alters the overall organization of the cell surface and cell circularity [(4π × area)/(perimeter)(2)] from 0.47 ± 0.06 units in mock-treated cells to 0.09 ± 0.03 units in S6K-overexpressing macrophages causing stellation and arborization of cell shape. This effect was partially reversed in cells expressing a kinase-inactive S6K mutant and was fully reversed in cells silenced with small interference RNA. Equally important is that S6K is itself regulated by phospholipids, specifically phosphatidic acid, whereby 300 nM 1,2-dioleoyl-sn-glycero-3-phosphate (DOPA), but not the control 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC), binds directly to S6K and causes an ∼ 2.9-fold increase in S6K catalytic activity. This was followed by an increase in Filamin A (FLNA) functionality as measured by phospho-FLNA (S(2152)) expression and by a subsequent elevation of actin nucleation. This reliance of S6K on phosphatidic acid (PA), a curvature-inducing phospholipid, explained the extra-large perimeter of cells that overexpressed S6K. Furthermore, the diversity of the response to S6K in several unrelated cell types (fibroblasts, leukocytes, and invasive cancer cells) that we report here indicates the existence of an underlying common mechanism in mammalian cells. This new signaling set, PA-S6K-FLNA-actin, sheds light for the first time into the morphogenic pathway of cytoskeletal structures that are crucial for adhesion and cell locomotion during inflammation and metastasis.

Distinct repression of translation by wortmannin and rapamycin

The role of phosphatidylinositol 3-kinase and FK506-binding protein rapamycin-associated protein (FRAP) in translational control has been examined by treating RD-rhabdomyosarcoma cells with wortmannin and rapamycin and studying the effects on cell-growth, translation initiation, and protein synthesis. Whereas wortmannin and rapamycin exhibit subtle effects on global translation, examination of individual mRNAs in sucrose gradients and of individual proteins in two-dimensional polyacrylamide gels reveals that wortmannin and rapamycin exhibit distinct effects on the translation of individual mRNAs. Wortmannin represses the synthesis of a third of cellular proteins, whereas rapamycin affects a subset of these proteins. Since ribosomal protein S6 was rapidly dephosphorylated following wortmannin and rapamycin treatment, and the phosphorylation status of the eukaryotic initiation factor 4E was unchanged, our data imply that the p70 signalling pathway has at least one branch-point upstream of FRAP leading to an additional route of translational control.

A human cDNA encoding the homologue of NADH: ubiquinone oxidoreductase subunit B13

A cDNA encoding the human homologue of bovine NADH:ubiquinone oxidoreductase (complex I of mitochondrial respiratory chain) subunit B13 has been isolated. The clone contains an open reading frame of 348 bp, 23 bp of 5'-untranslated sequence (UTR) and a long 3'UTR of 1088 bp. The deduced amino-acid sequence is 87% identical to bovine B13. Human B13 mRNA expression was observed in all tissues examined with highest levels in heart, skeletal muscle and brain. Southern analysis of human genomic DNA revealed the presence of multigene family.

Structural characterization of the mouse ribosomal protein S6-encoding gene

The gene encoding mouse ribosomal protein (r-protein) S6 is 2.7 kb in length, and is composed of five exons. The intron positions of the mouse S6 (Rps6) coincide exactly to those of the homologous human S6 (RPS6), but the last intron present in the human is absent in the mouse gene. The latter displays higher G + C content than the RPS6, both in the overall sequenced region and at the 3rd codon position. The promoter area is highly conserved between mouse and human, and contains several putative cis-acting elements. Comparison of the intronic sequences of both genes revealed surprisingly a high degree of identity (63%) within 350 bp of the first intron. Besides the single-copy Rsp6 there are up to 15 S6 family members, most likely processed pseudogenes. Characterization of the Rps6 provides a basis to study the functions of the mammalian S6 by gene targeting.

The human S3a ribosomal protein: sequence, location and cell-free transcription of the functional gene

The intron-containing gene encoding human ribosomal protein S3a (hRPS3a) was isolated by utilizing a PCR-based strategy to detect a gene-specific intron which was subsequently used as a probe for cloning of the entire gene. The hRPS3a gene is composed of six exons and five introns spanning 5013 bp. As described for other hRP-encoding genes, the promoter lacks a canonical TATA sequence and a defined CAAT box. Primer extension experiments, as well as cell-free transcription, revealed that a cytosine functions as the major transcription start point in a polypyrimidine region, but a guanosine at position -1 was also able to initiate transcription. Hybridization analysis of chromosomal DNA from a panel of human-rodent somatic cell hybrids revealed that hRPS3a is encoded by a single locus in the human genome, present on chromosome 4.

Structural organization and chromosomal localization of the human ribosomal protein L9 gene

The intron-containing gene for the human ribosomal protein L9 has been cloned, sequenced and localized. The gene is approximately 5.5 kb in length and contains 8 exons. Splice sites follow the AG/GT consensus rule. The message for human rpL9 is 712 nt in length and is detected in all tissues examined. In the adult, expression is highest in retina and liver while brain shows highest expression among the fetal tissues tested. The transcription start site contains an oligopyrimidine tract, TTCTTTCTT, similar to those found in other ribosomal protein genes. As in other previously characterized ribosomal protein genes, a TATA box is absent from the 5' flanking region but a number of elements recognized by common transcription factors are present including Sp1 sites, CACCC boxes, inverted CCAAT boxes, and GATA elements. Another possible element of interest in the rpL9 5' flanking region is RFX1 also found in the well characterized rat rpL30 promoter. The gene was mapped by fluorescent in situ hybridization to band 13p of chromosome 4. At least 8 possible pseudogenes are present in the human genome, one of which is on Xp. As assessed by Southern 'Zoo-blot' analysis and direct cDNA sequence comparison, the human ribosomal protein L9 gene, like other ribosomal protein genes, is highly conserved among mammals.

The L19 ribosomal protein gene (RPL19): gene organization, chromosomal mapping, and novel promoter region

The intron-containing genes encoding rat and human ribosomal protein L19 (RPL19) have been cloned. The DNA sequences of the entire rat RPL19 gene and the 5' end of the human RPL19 gene have been determined. Sequence comparison of corresponding regions of the two genes reveals a striking interspecies homology in the 5' upstream region, outside the transcribed and coding regions. The transcriptional start sites of the two genes have been determined and are identical. Both rat and human RPL19 genes have 5' ends associated with CpG islands. A promoter deletion analysis of the rat RPL19 gene suggests that this promoter may differ from those of all previously characterized ribosomal protein genes in requiring far upstream sequences for efficient gene expression. By fluorescence in situ hybridization analysis, the position of the human RPL19 gene has been sublocalized to 17q11 and may be coamplified with the erbB-2 gene in human breast cancer cells. The similarities and differences between RPL19 and other previously characterized ribosomal protein genes are discussed.

The mouse Fau gene: genomic structure, chromosomal localization, and characterization of two retropseudogenes

The Fau gene is the cellular homolog of the fox sequence of the Finkel-Biskis-Reilly murine sarcoma virus (FBR-MuSV). FBR-MuSV acquired the Fau gene by transduction in a transcriptional orientation opposite to that of the genomic Fau gene. The genomic structure of the mouse Fau gene (MMFAU) and its upstream elements have been determined and are similar to those of the human FAU gene. The gene consists of five exons and is located on chromosome 19. The first exon is not translated. The promoter region has no well-defined TATA box but contains the polypyrimidine initiator flanked by regions of high GC content (65%) and shows all of the characteristics of a housekeeping gene. The 5' end of the mRNA transcript was determined by 5' RACE analysis and is located, as expected, in the polypyrimidine initiator site. Furthermore, the sequences of two retropseudogenes (Fau-ps1 and Fau-ps2) are reported. Both pseudogenes are approximately 75% identical to the Fau cDNA, but both are shorter due to a deletion at the 5' end and do not encode a functional protein. Fau-prs is interrupted by an AG-rich region of about 350 bp within the S30 region of the Fau cDNA. Fau-ps1 was localized on chromosome 1 and Fau-ps2 on chromosome 7.

Rapamycin selectively inhibits translation of mRNAs encoding elongation factors and ribosomal proteins

The immunosuppressant rapamycin (RAP) has been demonstrated to specifically inhibit the activity of p70 S6 kinase (p70s6k) and subsequent phosphorylation of ribosomal S6 protein in mammalian cells. Addition of RAP to proliferating lymphoid cells resulted in inhibition of protein synthesis before any changes in the rate of cell proliferation. When the cellular composition of proteins was examined by gel electrophoresis, RAP dramatically inhibited synthesis of selective proteins, particularly elongation factor 2 (eEF-2). The inhibition of eEF-2 synthesis by RAP was at the translational level. Further, RAP inhibited the polysomal association of mRNAs encoding not only eEF-2 but also elongation factor 1-alpha and ribosomal proteins without affecting mRNA translation of any of a number of nonribosomal proteins. Since levels of activity of p70s6k are correlated with the rate of biosynthesis of eEF-2, p70s6k might be involved in coordinate translational regulation of ribosomal protein mRNAs in higher eukaryotes, which have a conserved sequence at their 5' end. Specific inhibition of ribosomal protein synthesis likely explains the differential antiproliferative effect of RAP on proliferating and mitogen-activated quiescent cells.

Mitogenesis and protein synthesis: a role for ribosomal protein S6 phosphorylation?

It has been known for 20 years that the ribosomal protein S6 is rapidly phosphorylated when cells are stimulated to grow or divide. Furthermore, numerous studies have documented that there is a strong correlation between increases in S6 phosphorylation and protein synthesis, leading to the idea that S6 phosphorylation is involved in up-regulating translation. In an attempt to define a mechanism by which S6 phosphorylation exerts translational control, other studies have focused on characterizing the sites of phosphorylation of this protein and its location within the ribosome. Recent data show that S6 is a protein which may have diverse cellular functions and is essential for normal development, and that it may be involved in the translational regulation of a specific class of messages.

Structure and function of ribosomal protein S4 genes on the human and mouse sex chromosomes

The human sex-linked genes RPS4X and RPS4Y encode distinct isoforms of ribosomal protein S4. Insufficient expression of S4 may play a role in the development of Turner syndrome, the complex human phenotype associated with monosomy X. In mice, the S4 protein is encoded by an X-linked gene, Rps4, and is identical to human S4X; there is no mouse Y homolog. We report here the organization of the human RPS4X and RPS4Y and mouse Rps4 genes. Each gene comprises seven exons; the positions of introns are conserved. The 5' flanking sequences of human RPS4X and mouse Rps4 are very similar, while RPS4Y diverges shortly upstream of the transcription start site. In chickens, S4 is encoded by a single gene that is not sex linked. The chicken protein differs from human S4X by four amino acid substitutions, all within a region encoded by a single exon. Three of the four substitutions are also present in human S4Y, suggesting that the chicken S4 gene may have arisen by recombination between S4X- and S4Y-like sequences. Using isoform-specific antisera, we determined that human S4X and S4Y are both present in translationally active ribosomes. S4Y is about 10 to 15% as abundant as S4X in ribosomes from normal male placental tissue and 46,XY cultured cells. In 49,XYYYY cells, S4Y is about half as abundant as S4X. In 49,XXXXY cells, S4Y is barely detectable. These results bear on the hypothesized role of S4 deficiency in Turner syndrome.

Structure and function of ribosomal protein S4 genes on the human and mouse sex chromosomes

The human sex-linked genes RPS4X and RPS4Y encode distinct isoforms of ribosomal protein S4. Insufficient expression of S4 may play a role in the development of Turner syndrome, the complex human phenotype associated with monosomy X. In mice, the S4 protein is encoded by an X-linked gene, Rps4, and is identical to human S4X; there is no mouse Y homolog. We report here the organization of the human RPS4X and RPS4Y and mouse Rps4 genes. Each gene comprises seven exons; the positions of introns are conserved. The 5' flanking sequences of human RPS4X and mouse Rps4 are very similar, while RPS4Y diverges shortly upstream of the transcription start site. In chickens, S4 is encoded by a single gene that is not sex linked. The chicken protein differs from human S4X by four amino acid substitutions, all within a region encoded by a single exon. Three of the four substitutions are also present in human S4Y, suggesting that the chicken S4 gene may have arisen by recombination between S4X- and S4Y-like sequences. Using isoform-specific antisera, we determined that human S4X and S4Y are both present in translationally active ribosomes. S4Y is about 10 to 15% as abundant as S4X in ribosomes from normal male placental tissue and 46,XY cultured cells. In 49,XYYYY cells, S4Y is about half as abundant as S4X. In 49,XXXXY cells, S4Y is barely detectable. These results bear on the hypothesized role of S4 deficiency in Turner syndrome.

Determinants of translational fidelity and efficiency in vertebrate mRNAs

This article reviews current knowledge on the mechanisms affecting the fidelity of initiation codon selection, and discusses the effects of structural features in the 5′-non-coding region on the efficiency of translation of messenger RNA molecules.

A complete cDNA sequence for ribosomal protein S6 of Xenopus laevis

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