The only eukaryotic mRNAs that are not polyadenylated are the replication-dependent histone mRNAs in metazoans. The sea urchin genome contains two sets of histone genes that encode non-polyadenylated mRNAs. One of these sets is a tandemly repeated gene cluster with a 5.6-kb repeat unit containing one copy of each of the five alpha-histone genes and is present as a single large cluster which spans over 1 Mb. There is a second set of genes, consisting of 39 genes, containing two histone H1 genes, 34 genes encoding core histone proteins (H2a, H2b, H3 and H4) and three genes expressed only in the testis. Unlike vertebrates where these genes are clustered, the sea urchin late histone genes, expressed in embryos, larvae and adults, are dispersed throughout the genome. There are also genes encoding polyadenylated histone mRNAs, which encode histone variants, including all variants found in other metazoans, as well as a unique set of five cleavage stage histone proteins expressed in oocytes. The cleavage stage histone H1 is the orthologue of an oocyte-specific histone H1 protein found in vertebrates. 相似文献
The mouse histone mRNAs coded for by three different cloned DNA fragments have been characterized. Two of these cloned DNA fragments, MM221 and MM291, located on chromosome 13, code for H3, H2b and H2a histone mRNAs, which are expressed at low levels in cultured mouse cells and fetal mice. The other DNA fragment, MM614, located on chromosome 3, codes for an H3 and an H2a mRNA, which are expressed at high levels in these cells. The mRNAs for each histone protein share common coding region sequences, while the untranslated regions of all the genes have diverged significantly, as judged by S1 nuclease mapping. Amino acid substitutions in some H3, H2a and H2b proteins are detected as internal cleavages in the S1 nuclease maps. All of these genes code for replication variant histone mRNAs, which are regulated in parallel with DNA synthesis. 相似文献
When DNA synthesis is inhibited, the mRNAs coding for the replication-dependent histone proteins are selectively destabilized. The histone genes have been altered and reintroduced into tk- mouse L cells by cotransfection with the herpesvirus thymidine kinase gene. Two features of the mRNA are necessary for regulation of degradation: first, the hairpin loop must be present at the 3' end of the histone mRNA; and second, the histone mRNA must be capable of being translated to within 300 nucleotides of the 3' end of the RNA. Polyadenylated histone mRNAs are stable, as are histone mRNAs that contain in-frame termination codons early in the coding region or 500 nucleotide 3' untranslated regions with a normal hairpin loop at the 3' end. 相似文献
We have studied the structure and expression of histone H2B mRNA and genes in the parasitic protozoan Leishmania enrietti. A genomic clone containing three tandemly repeated genes has been sequenced and shown to encode three identical histone proteins and two types of closely related mRNA sequence. We have also sequenced three independent cDNA clones and demonstrated that the Leishmania H2B mRNAs are polyadenylated, similar to the basal histone mRNAs of higher eucaryotes and the histone mRNAs of yeast. In addition, the Leishmania mRNAs contain inverted repeats near the poly(A) tail which could form stem-loops similar in secondary structure, but not in sequence, to the 3' stem-loops of nonpolyadenylated replication-dependent histones of higher eucaryotes. Unlike the replication-dependent histones, the Leishmania histone H2B mRNAs do not decrease in abundance following treatment with inhibitors of DNA synthesis. The histone mRNAs are differentially expressed during the parasite life cycle and accumulate to a higher level in the extracellular promastigotes (the form which in nature lives within the gut of the insect vector) than in the intracellular amastigotes (the form that lives within the mammalian host macrophages). 相似文献
The relative cytoplasmic accumulation of the individual histone mRNAs in sea urchins was determined by gel analysis of 3H-labeled cytoplasmic RNA isolated from embryos of the early cleavage through the mesenchyme blastula stages. A number of separate determinations showed that H1 mRNA accumulates at a molar ratio of 0.5 or less compared with each of the H2 or H3 core histone mRNAs through approximately the first 12 h of embryonic development. After this time, the accumulation of H1 mRNA increases relative to the core histone mRNAs, and approximately equimolar amounts of the histone mRNAs are produced by about the 14-h stage. The equimolar synthesis of H1 mRNA appears to be transient, returning to 0.5-molar levels several hours later. The increase in H1 mRNA accumulation, relative to the core histone RNAs, is coincident with the transition from expression of the early (alpha) sea urchin histone gene set to the late histone genes. Since all five of the early histone genes occur in a 1:1 ratio within repeating units, the data suggest that the genes within a single repeat, or their immediate products, are individually regulated. Gel analysis of the proteins synthesized in vivo by embryos demonstrates that the pattern of synthesis of the histone proteins reflects the changing ratios of the histone mRNAs. 相似文献
We have examined the molecular mechanisms responsible for the shifts in histone protein phenotype during embryogenesis in the sea urchinStrongylocentrotus purpuratus. The H1, H2A, and H2B classes of histone synthesized at the earliest stages of cleavage are heterogeneous: These proteins are replaced at late embryogenesis by a different set of histone-like polypeptides, some of which are also heterogeneous. The H3 and H4 histones appear to be homogeneous classes and remain constant. We have isolated from both early and late embryos the individual messenger RNAs coding for each of the multiple protein subtypes. The RNAs were isolated by hybridization to cloned DNA segments coding for a single histone protein or by elution from polyacrylamide gels. Each RNA was then analyzed and identified by its mobility on polyacrylamide gels and by its template activity in the wheat germ cell-free protein synthesizing system. The mRNAs for each of the five early histone protein classes are heterogeneous in size and differ from the late stage templates. The late mRNAs consist of at least 11 separable types coding for the 5 classes of histones. Each of the 11 has been separated and identified. The late stage proteins were shown to be authentic histones since many of their templates hybridize with histone coding DNA. The early and late stage mRNAs are transcribed from different sets of histone genes since (1) late stage H1 and H2A mRNAs fail to hybridize to cloned early stage histone genes under ideal conditions for detecting homologous early stage hybrids, (2) late stage H2B, H3, and H4 RNA/DNA hybrids melt at 14, 11, and 11°C lower, respectively, than do homologous RNA/DNA hybrids, and (3) purified late stage mRNAs direct the synthesis of the variant histone proteins which are synthesized only during later stages. The time course of synthesis of the late stage mRNAs suggests that they appear many hours before the late histone proteins can be detected, possibly as early as fertilization. In addition, early mRNAs are synthesized in small quantities as late as 40 hr after fertilization, during gastrulation. Thus, the major modulations of histone gene expression are neither abrupt nor an absolute on-off switch, and may represent only a gradual and relative repression of early gene expression. Two histones are detected only transiently during early cleavage. The mRNA for one of them, a subtype of H2A, can be detected in the cytoplasm for as long as 40 hr after fertilization. However, template activity for the other, a subtype of H2B, can be detected only at the blastula stage. Thus, the histone genes represent a complex multigene family that is developmentally modulated. 相似文献
Sea urchin (S. purpuratus) histone DNA of constructed plasmid chimeras cloned in E. coli was cleaved with the restriction endonucleases Eco RI, Hind III, Sal I, Bam I, and Hha I. The resulting fragments were ordered and isolated directly from agarose gels or cloned into other plasmids. Each fragment hybridized to one or another of the five histone mRNAs and elucidated the order of the histone genes in each of the cloned fragments. Some DNA did not hybridize to histone mRNAs and was identified as spacer DNA located between coding regions.Total sea urchin DNA was cleaved with restriction endonucleases, fractionated on agarose gels, and hybridized to histone mRNAs or histone DNA. The results revealed the order of the five histone genes in the histone gene repeat unit and demonstrate that the histone spacer DNAs have little sequence homology to other genes. Exonuclease III digestion of specific linear chimeric histone DNA plasmids followed by hybridization with mRNAs demonstrated the existence of all five histone genes on one strand of DNA and the 5′-3′ polarity of that strand. These results, in conjunction with the data of Wu et al. (1976), allow us to construct a map of coding and spacer sequences in the transcribed strand of the S. purpuratus histone gene repeat unit: 相似文献
The replication-dependent histone mRNAs in metazoa are not polyadenylated, in contrast to the bulk of mRNA. Instead, they contain an RNA stem-loop (SL) structure close to the 3' end of the mature RNA, and this 3' end is generated by cleavage using a machinery involving the U7 snRNP and protein factors such as the stem-loop binding protein (SLBP). This machinery of 3' end processing is related to that of polyadenylation as protein components are shared between the systems. It is commonly believed that histone 3' end processing is restricted to metazoa and green algae. In contrast, polyadenylation is ubiquitous in Eukarya. However, using computational approaches, we have now identified components of histone 3' end processing in a number of protozoa. Thus, the histone mRNA stem-loop structure as well as the SLBP protein are present in many different protozoa, including Dictyostelium, alveolates, Trypanosoma, and Trichomonas. These results show that the histone 3' end processing machinery is more ancient than previously anticipated and can be traced to the root of the eukaryotic phylogenetic tree. We also identified histone mRNAs from both metazoa and protozoa that are polyadenylated but also contain the signals characteristic of histone 3' end processing. These results provide further evidence that some histone genes are regulated at the level of 3' end processing to produce either polyadenylated RNAs or RNAs with the 3' end characteristic of replication-dependent histone mRNAs. 相似文献
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