D J Roufa

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.

Emetine resistance of Chinese hamster cells: structures of wild-type and mutant ribosomal protein S14 mRNAs.

The Chinese hamster ovary (CHO) cell 40S ribosomal subunit protein S14 provides a unique opportunity to investigate an important mammalian housekeeping gene and its mRNA and protein products. The S14 gene appears to be single copy, and CHO cell S14 mutants have been isolated as emetine-resistant (emtB) clones in tissue culture. Thus, S14 is the only mammalian ribosomal protein whose gene structure and function are amenable to straightforward genetic and biochemical analysis. Recently, we isolated a wild-type Chinese hamster lung cell cDNA clone, pCS14-1, including an almost complete copy of the ribosomal protein S14 message (N. Nakamichi, D. D. Rhoads, and D. J. Roufa, J. Biol. Chem. 258: 13236-13242, 1983). Here we describe comparable cDNAs from wild-type and emtB CHO cells. We report both mRNA and polypeptide sequences of the wild-type and mutant ribosomal protein transcripts. As a consequence of the genetic methods used to obtain our emetine-resistant mutants, the emtB S14 cDNAs differ from wild-type cDNA by single-base changes. Physical and chemical features of polypeptides encoded by the cDNAs are consistent with well-characterized S14 protein polymorphisms. The three emtB mutations analyzed affect two adjacent arginine codons within the very basic S14 carboxyl region, indicating a significant role for this portion of the protein in the function and architecture of the mammalian 40S ribosomal subunit.

A mammalian origin of bidirectional DNA replication within the Chinese hamster RPS14 locus.

Two complementary experimental approaches have been used to identify a chromosomal origin of bidirectional DNA replication within or immediately downstream of the Chinese hamster ribosomal protein S14 gene (RPS14). The replication origin, designated oriS14, maps within a 1.6- to 2.0-kbp region of RPS14 that includes the genes third and fourth introns, exons IV plus V, and approximately 500 bp of proximal downstream flanking DNA. The nucleic acid sequence encoding oriS14 closely resembles the other mammalian chromosomal replication origins whose primary structures are known. It contains DNA binding sites for a large number of transcription factors, replication proteins, and mammalian oncogenes as well as several dinucleotide repeat motifs, an AT-rich region, and a sequence that is likely to bend the DNA. In contrast to the other well-characterized mammalian replication origins, which are autosomal and therefore carried as two copies per somatic cell, oriS14 is encoded by single-copy DNA within a hemizygous segment of chromosome 2q in CHO-K1 cells. Also, other known mammalian replication origins are situated in nontranscribed, intergenic DNA, whereas the DNA sequence encoding oriS14 substantially overlaps the transcribed portion of a constitutively expressed housekeeping gene.

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.

Ribosomal protein S14 is encoded by a pair of highly conserved, adjacent genes on the X chromosome of Drosophila melanogaster.

We describe a Drosophila DNA clone of tandemly duplicated genes encoding an amino acid sequence nearly identical to human ribosomal protein S14 and yeast rp59. Despite their remarkably similar exons, the locations and sizes of introns differ radically among the Drosophila, human, and yeast (Saccharomyces cerevisiae) ribosomal protein genes. Transcripts of both Drosophila RPS14 genes were detected in embryonic and adult tissues and are the same length as mammalian S14 message. Drosophila RPS14 was mapped to region 7C5-9 on the X chromosome. This interval also encodes a previously characterized Minute locus, M(1)7C.

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

DNA sequences complementary to six mammalian ribosomal protein (r-protein) cDNAs are assigned to human chromosomal linkage groups in human-Chinese hamster hybrid cell clones. Ten r-protein DNA fragments map to chromosomes 5, 8 and 17, indicating that these important, housekeeping genes are distributed to multiple sites in the human genome. Each of the chromosome assignments, determined initially by surveying Chinese hamster-human hybrid cell clones with complex karyotypes using Chinese hamster and human cDNA probes, were confirmed in critical minipanels of highly reduced or monochromosomal hybrid cells. As all 10 fragments mapped to only three human chromosomes, r-protein sequences appear to be distributed nonrandomly within human DNA. The r-protein S14 sequence assigned to human chromosome 5 (5q23–5q33) rescues Chinese hamster emetine-resistance mutations (emt b)in interspecific hybrids. Therefore, this sequence corresponds to the transcriptionally active human RPS14gene. In contrast, other r-protein DNA sequences examined likely are a mixture of functional genes and inactive pseudogenes.

Replication of a mammalian genome: the role of de novo protein biosynthesis during S phase

Abstract ts14 is a temperature-sensitive Chinese hamster lung cell mutant that ceases protein biosynthesis within a short time of transfer to nonpermissive temperature (Haralson and Roufa, 1975; Roufa and Haralson, 1975; Roufa and Reed, 1975). This mutant contains a revertible, presumably a point mutation that renders its 60S ribosomal subunit thermolabile (Haralson and Roufa, 1975). In this report, we describe the relationship between the conditional ability of ts14 to synthesize protein during S phase and the replication of its DNA. After transfer to nonpermissive temperature (39°C), where ts14 synthesizes protein at a rate approximately 20 fold less than wild-type cells, synchronous cultures of the mutant performed all the processes required for replication of their DNA. During prolonged incubations at nonpermissive temperature, S phase ts14 completed approximately one round of DNA replication semi-conservatively as judged by density-transfer experiments. Pulse-labeling experiments performed on S phase cells revealed that ts14 synthesized the intermediates of discontinuous DNA replication at nonpermissive and permissive temperatures at similar rates. In these tests, the mutant was not substantially different from wild-type at both culture temperatures. At the nonpermissive temperature, however, ts14 synthesized significantly less nuclear protein (that is, histone) than did wild-type cells, and the mutants chromatin appeared deficient in histone by virtue of its increased sensitivity to nuclease.

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 densely methylated DNA Island is associated with a chromosomal replication origin in the humanRPS14 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.

Replication of viral DNA sequences integrated within the chromatin of SV40-transformed chinese hamster lung cells

To determine when during S phase integrated viral DNA sequences in several tsA SV40-transformed Chinese hamster cell clones replicate, we pulse-labeled cultures with BrdUrd and subsequently collected mitotic cells during sequential time intervals. Restriction endonuclease mapping indicated that each of the three SV40-transformed Chinese hamster lung cell clones contained a single viral DNA sequence at a different, but in each case unique, chromosomal site. DNA was extracted from each population of mitotic cells and then was resolved into dense, BrdUrd-containing and light, unsubstituted DNA fractions by cesium chloride gradient centrifugation. In each pair of samples obtained, we measured viral DNA sequences by solution hybridization using single-stranded SV40 32P-labeled DNA probes. Our results support the conclusions that specific genes within a mammalian DNA are programmed to replicate at particular times during S phase, and that the SV40 A gene product, large T antigen, programs integrated viral DNA sequences to replicate very early in S phase. The fractions of viral DNA replicated early in S phase appeared to correlate with each clones content of functional large T antigen at permissive and nonpermissive culture temperatures.