The organization of sea urchin histone genes

Sucrose gradient analysis of total sea urchin DNA cleaved with theEcoRI andHind III restriction endonucleases and identification of histone coding gene sequences by hybridization with histone mRNA have elucidated the basic organization of the histone gene repeat unit. These data, plus results obtained by electrophoretic analysis of purified endonuclease-cleaved sea urchin histone DNA and hybridization with cRNA transcribed from the eucaryotic segment of constructed plasmid chimeras cloned in E. coli, show that the several DNA sequences coding for individual histone proteins are intermingled in a 7 kilobase (kb) repeat unit. Cleavage of total sea urchin DNA withEcoRI produces 2.2 and 4.8 kb fragments which are homologous with the two cloned fragments, and which are contained in a 7 kbHind III fragment. Cleavage with both enzymes reveals that the 2.2 kbEcoRI fragment contains aHind III site 0.15–0.2 kb from an end. RNA · DNA hybridization between chimeric plasmid DNA and purified individual mRNAs isolated from sea urchin embryo polyribosomes has been used to assign coding sequences to either the 2.2 or 4.8 kb region of the histone DNA repeat unit. A map of the histone genes is proposed.     

Histone gene switch in the sea urchin embryo. Identification of late embryonic histone messenger ribonucleic acids and the control of their synthesis.

During embryogenesis in the sea urchin Strongylocentrotus purpuratus, there is a shift from one histone mRNA population to another. The early and late embryonic histone mRNAs, previously shown to differ considerably in sequence from each other by hybrid melting studies, are shown here to differ also in electrophoretic mobility on polyacrylamide gels as the positions of the early and late mRNAs are completely noncoincident. The various species of both early and late samples are identified as particular histone mRNAs by hybridization to cloned histone DNAs containing part of the early-type repeat unit or to restriction enzyme fragments derived from these unit. Four bands in the early mRNA sample are identified as H1, H3, H2A " H2B, and H4 mRNA while at least 10 bands can be seen in the late mRNA preparation with unambiguous identification of H1, H2B, and H4 mRNAs. A cluster of late species is shown to contain both H3 and H2A mRNA. When a polysomal RNA preparation from the 26-h embryo is hybridized to the histone DNA, eluted, and then translated in vitro in a wheat germ system, the histone products migrate in the position of late histones when subjected to electrophoresis on Triton X-urea gels. Using DNA which contains genes for H2A + H3 or H2A alone, we demonstrate the specificity of the early-type DNA probes for these two late histones. Therefore, by hybridization of newly synthesized RNAs and translation of the total polysomal RNA present in the late embryo, it is shown that mRNAs for all five histone classes may cross-react with the cloned early-type DNA. The hybrids formed, however, are much less stable than those formed with the early histone mRNA. In vitro translation of total cytoplasmic RNA from various embryonic stages indicates that transition between the two classes occurs during most of the blastula period.     

Evidences of two different sets of histone genes active during embryogenesis of the sea urchin Paracentrotus lividus.

Histone mRNAs at different stages of development were purified by hybridization with the cloned homologous histone genes. The electrophoretic patterns of oocytes, 2-4 blastomeres, 64 cells and morula histone mRNAs was found to be identical, whereas the electrophoretic pattern of mesenchyme blastula histone mRNA was markedly different. The cloned histone DNA of P.lividus was hybridized with the RNA of each stage. The Tm was 74 degrees C in all cases except for the mesenchyme histone mRNAs whose Tm was 59 degrees C, thus suggesting that at least two different clusters of histone genes are active in the course of the sea urchin development.     

Histone genes in macronuclear DNA of the ciliate Stylonychia mytilus

DNA in the macronucleus of Stylonychia mytilus exists as discrete gene-sized fragments which are derived from micronuclear DNA through a series of well-defined developmental events. It has been proposed that each of the DNA fragments might represent a gene and its controlling elements. We have investigated this possibility using genes which code for the five histone proteins. Macronuclear DNA fragments were fractionated according to size by agarose gel electrophoresis, the fragments transferred to nitrocellulose filters using the technique of Southern, and the filter-bound DNA hybridized with labeled cloned histone genes of the sea urchin, Psammechinus miliaris. Results indicate, first, that sequences homologous to the five individual histone gene probes are present in discrete macronuclear fragments which appear as bands in the gel hybridization assay. Secondly, for each of the five individual histone gene probes the homologous DNA fragments are several in number, ranging in size from 7.6 Kb (Kilo base pairs) to 0.73 Kb. For example, the largest of six detected fragments hybridizing to the H3 gene probe contains approximately 10 times the amount of DNA required to code for a Stylonychia H3 histone. The smallest detected fragment hybridizing to the H3 probe contains enough DNA to code for approximately two copies of the histone. Finally, in general, no two histone gene probes hybridized to the same macronuclear DNA fragment. This result indicates that genes coding for the five histones in Stylonychia are not located together on the same macronuclear DNA fragments and implies that the five functionally related genes would not be transcribed together as a polycistronic unit.     

Molecular analysis of the histone gene cluster of Psammechinus miliaris: II. The arrangement of the five histone-coding and spacer sequences

Histone DNA of Psammechinus miliaris was obtained in an enriched form by buoyant density gradient centrifugation and was cleaved into 6 kb repeat units (Birnstiel et al., 1975a) by the action of the specific endonucleases EcoRI and HindIII. Since it was suspected that the 6 kb unit harbored all five histone-coding sequences, the histone DNA unit was subdivided into five segments with the aim of providing five fragments carrying just one coding sequence each. This was achieved by the combined use of EcoRI HindII, HindIII, and Hpa I. A physical map was constructed from the overlaps arising in these restriction experiments. Each of the five segments was shown to hybridize uniquely with just one of the five highly purified histone mRNAs (Gross et al., 1976a). By this procedure, the order of the mRNA sequences on the histone DNA was found to be a, c, d, b, e (Gross et al., 1976a), and hence of the protein coding sequences H4, H2B, H3, H2A, and H1. Further evidence is presented that the 6 kb repeat unit, amplified by means of a Murray λ vector phage, contains AT-rich DNA sequences which would be expected not to code for histone proteins.     

The nicking endonuclease N.BstNBI is closely related to Type IIs restriction endonucleases MlyI and PleI

N.BstNBI is a nicking endonuclease that recognizes the sequence GAGTC and nicks the top strand preferentially. The Type IIs restriction endonucleases PleI and MlyI also recognize GAGTC, but cleave both DNA strands. Cloning and sequencing the genes encoding each of these three endonucleases discloses significant sequence similarities. Mutagenesis studies reveal a conserved set of catalytic residues among the three endonucleases, suggesting that they are closely related to each other. Furthermore, PleI and MlyI contain a single active site for DNA cleavage. The results from cleavage assays show that the reactions catalyzed by PleI and MlyI are sequential two step processes. The double-stranded DNA is first nicked on one DNA strand and then further cleaved on the second strand to form linear DNA. Gel filtration analysis shows that MlyI dimerizes in the presence of a cognate DNA and Ca²⁺ whereas N.BstNBI remains a monomer, implicating dimerization as a requisite for the second strand cleavage. We suggest that N.BstNBI, MlyI and PleI diverged from a common ancestor and propose that N.BstNBI differs from MlyI and PleI in having an extremely limited second strand cleavage activity, resulting in a site-specific nicking endonuclease.     

The relative positions of sea urchin histone genes on the chimeric plasmids pSp2 and pSp17 as studied by electron microscopy

The relative positions of the sea urchin histone genes and the spacer regions on the chimeric plasmids pSp2 and pSp17 have been mapped by hybridizing total histone messenger RNA to single strands of the plasmid DNAs. The lengths and spacing between the several RNA:DNA duplex regions on the single strands of DNA were measured by the gene 32-ethidium bromide electron microscope mapping method. We find that the genes are interdigitated with spacer sequences of different lengths; that there are three coding sequences on pSp2, all on the same strand, with the relative order H1, H4, and B4; and that there are two coding sequences on pSp17, both on the same strand, corresponding to the messages denoted B1 and B2–B3, where B4, B1, and B2–3 are electrophoretically resolved components of histone mRNA, all of size intermediate between the larger H1 and the smaller H4 message.     

Rapid purification of biologically active individual histone messenger RNAs by hybridization to cloned DNA linked to cellulose.

We describe a rapid and simple method for the purification of biologically active messenger RNAs. The method allows the isolation in a few hours of specific mRNAs from either whole cell or polysomal RNA even if the RNA represents less than 1% of the starting molecules. We used, as a model, cloned sea urchin (Strongylocentrotus purpuratus) histone gene fragments linked to cellulose by the method of B. E. Noyes & G. R. Stark (1975) Cell 5, 301--310) as hybridization probes to isolate specific histone mRNAs from whole cell and polysomal RNA extracts. RNAs isolated in this manner maintain their biological activity, serving as templates for histone proteins in a wheat-germ, cell-free protein translation system. In addition, radiolabeled histone-specific RNA purified from cleavage stage sea urchin embryos, pulse labeled for short periods of time and analyzed on denaturing polyacrylamide gels, was the same size as mature histone mRNA's.     

A simple method to recover intact high molecular weight RNA and DNA after electrophoretic separation in low gelling temperature agarose gels.

Defined RNA fractions can be recovered from low gelling temperature agarose gels by a combination of agarose melting at 65°C and phenol extraction. By this approach RNA molecules up to a size of 37 kb can be eluted undegraded with a recovery of 60–90%. The method is applicable also to DNA and the eluted DNA can be correctly cleaved with restriction endonucleases as shown for λDNA using EcoRI.     

The arrangement of simian virus 40 sequences in the DNA of transformed cells.

High molecular weight DNA, isolated from eleven cloned lines of rat cells independently transformed by SV40, was cleaved with various restriction endonucleases. The DNA was fractionated by electrophoresis through agarose gels, denatured in situ, transferred directly to sheets of nitrocellulose as described by Southern (1975), and hybridized to SV40 DNA labeled in vitro to high specific activity. The location of viral sequences among the fragments of transformed cell DNA was determined by autoradiography. The DNAs of seven of the cell lines contained viral sequences in fragments of many different sizes. The remaining four cell lines each contain a single insertion of viral DNA at a different chromosomal location. The junctions between viral and cellular sequences map at different places on the viral genome.     

An unusual evolutionary behaviour of a sea urchin histone gene cluster

DNA sequences of cloned histone coding sequences and spacers of sea urchin species that diverged long ago in evolution were compared. The highly repeated H4 and H3 genes active during early embryogenesis had evolved (in their silent sites) at a rate (0.5-0.6% base changes/Myr) similar to single-copy protein-coding genes and nearly as fast as spacer DNA (0.7% base changes/Myr) and unique DNA. Thus, evolution in the major histone genes conforms to a universal evolutionary clock based on the rate of base sequence change. By contrast, the H4 and H3 coding sequences and a non-transcribed spacer of the DNA clone h19 of Psammechinus miliaris show an exceptionally low rate of sequence evolution only 1/100 to 1/200 that predicted from the clock hypothesis. According to the classical model of gene inheritance, the h19 DNA sequences in the Psammechinus genome require unusual conservation mechanisms by selection at the level of the gene and spacer sequences. An alternative explanation could be recent horizontal gene transfer of a histone gene cluster from the very distantly related Strongylocentrotus dröbachiensis to the P. miliaris genome.     

Sa/I restriction endonuclease maps of FII incompatibility group R plasmids.

SalI restriction endonuclease maps of FII incompatibility group R plasmids NR1, NR84, and R6 have been determined by sequential digestion of plasmid DNA with EcoRI and SalI and subsequent analysis of the fragments by electrophoresis on agarose gels. In the composite R plasmid NR1 there are five SalI sites, one in the r-determinants component and four in the RTF-Tc component. SalI cleavage of transitioned NR1 DNA, which contains tandem sequences of the r-determinants in a head-to-tail orientation, produces the five original bands plus a single new amplified band whose mobility on agarose gels corresponds to the monomer r-determinants DNA. NR84 has a total of four SalI sites. It is missing one of the SalI sites near the repA locus. R6 has five SalI sites, four the same as those of NR84, and one additional site within the Km transposon Tn601.     

Chloroplast ribosomal RNA genes in Euglena gracilis exist as three clustered tandem repeats

Chloroplast ribosomal DNA from Euglena gracilis was partially purified, digested with restriction endonucleases BamHI or EcoRI and cloned into bacterial plasmids. Plasmids containing the ribosomal DNA were identified by their ability to hybridize to chloroplast ribosomal RNA and were physically mapped using restriction endonucleases BamHI, EcoRI, HindIII and HpaI. The nucleotide sequences coding for the 16S and the 23S chloroplast ribosomal RNAs were located on these plasmids by hybridizing the individual RNAs to denatured restriction endonuclease DNA fragments immobilized on nitrocellulose filters. Restriction endonuclease fragments from chloroplast DNA were analyzed in a similar fashion. These data permitted the localization on a BamHI map of the chloroplast DNA three tandemly arranged chloroplast ribosomal RNA genes. Each ribosomal RNA gene consisted of a 4.6 kilobase pair region coding for the 16S and 23S ribosomal RNAs and a 0.8 kilobase pair spacer region. The chloroplast ribosomal DNA represented 12% of the chloroplast DNA and is G + C rich.     

Multiple alpha and beta tubulin genes represent unlinked and dispersed gene families

Cloned cDNA sequences specific for alpha or beta tubulin mRNAs have been used to show that the multigene families which encode either alpha or beta tubulin are unlinked and dispersed throughout the chicken genome. Fractions of chicken chromosomes partially purified by centrifugation on a sucrose gradient were digested with restriction endonucleases and electrophoresed on agarose gels. The DNA was transferred to nitrocellulose filters and hybridized to labeled probes constructed from cloned cDNA sequences specific for alpha or beta tubulin. We find alpha tubulin sequences on four different chicken chromosomes and beta tubulin sequences on at least two different chromosomes. Moreover, using chicken chromosomes further purified with a fluorescent cell sorter, we have been able unambiguously to localize alpha tubulin genes to chromosome 1 and chromosome 8 and two of the beta genes to chromosome 2.