Molecular cloning of a pea H1 histone cDNA

Advances in COVID-19 mRNA vaccine development

To date, the coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has determined 399,600,607 cases and 5,757,562 deaths worldwide. COVID-19 is a serious threat to human health globally. The World Health Organization (WHO) has declared COVID-19 pandemic a major public health emergency. Vaccination is the most effective and economical intervention for controlling the spread of epidemics, and consequently saving lives and protecting the health of the population. Various techniques have been employed in the development of COVID-19 vaccines. Among these, the COVID-19 messenger RNA (mRNA) vaccine has been drawing increasing attention owing to its great application prospects and advantages, which include short development cycle, easy industrialization, simple production process, flexibility to respond to new variants, and the capacity to induce better immune response. This review summarizes current knowledge on the structural characteristics, antigen design strategies, delivery systems, industrialization potential, quality control, latest clinical trials and real-world data of COVID-19 mRNA vaccines as well as mRNA technology. Current challenges and future directions in the development of preventive mRNA vaccines for major infectious diseases are also discussed.

Phylogenetic reconstruction at the species and intraspecies levels in the genus Pisum (L.) (peas) using a histone H1 gene

A phylogenetic analysis of the genus Pisum (peas), embracing diverse wild and cultivated forms, which evoke problems with species delimitation, was carried out based on a gene coding for histone H1, a protein that has a long and variable functional C-terminal domain. Phylogenetic trees were reconstructed on the basis of the coding sequence of the gene His5 of H1 subtype 5 in 65 pea accessions. Early separation of a clear-cut wild species Pisum fulvum is well supported, while cultivated species Pisum abyssinicum appears as a small branch within Pisum sativum. Another robust branch within P. sativum includes some wild and almost all cultivated representatives of P. sativum. Other wild representatives form diverse but rather subtle branches. In a subset of accessions, PsbA-trnH chloroplast intergenic spacer was also analysed and found less informative than His5. A number of accessions of cultivated peas from remote regions have a His5 allele of identical sequence, encoding an electrophoretically slow protein product, which earlier attracted attention as likely positively selected in harsh climate conditions. In PsbA-trnH, a 8bp deletion was found, which marks cultivated representatives of P. sativum.

Expression profiles of a banana fruit linker histone H1 gene MaHIS1 and its interaction with a WRKY transcription factor

Chromatin remodeling-related proteins, such as linker histone H1, involving in fruit ripening and stress responses are poorly understood. In the present study, a novel cDNA encoding linker histone H1 gene, designated as MaHIS1 was isolated and characterized from banana fruit. The full-length cDNA sequence was 1,253 bp with an open-reading frame (ORF) of 948 bp, encoding 315 amino acids with a molecular weight of 31.98 kDa and a theoretical isoelectric point of 10.67. Subcellular localization analysis showed that MaHIS1 was a nucleus-localized protein. Real-time PCR analysis indicated that expression of MaHIS1 gene is induced by external and internal ethylene during fruit postharvest ripening. Accumulation of MaHIS1 transcript was also obviously enhanced by exogenous hormones, including methyl jasmonate, abscisic acid, and hydrogen peroxide (H₂O₂), as well as stresses, such as chilling and pathogen Colletotrichum musae infection. Moreover, yeast two-hybrid and bimolecular fluorescence complementation assays showed that MaHIS1 could interact with a transcription factor (TF) MaWRKY1. Taken together, our results suggest that MaHIS1 may be related to ripening and stress responses of banana fruit, and be likely functionally coordinating with MaWRKY1 in these physiological processes.

KEY MESSAGE

MaHIS1 may be related to ripening and stress responses of banana fruit, and it also could interact with WRKY TF, which expands the very limited information regarding the functions of linker histone H1 in fruits.

Phenotypic effect of substitution of allelic variants for a histone H1 subtype specific for growing tissues in the garden pea (Pisum sativum L.)

In pea, subtype H1-7 of histone H1 is specific for young actively growing tissues and disappears from chromatin of mature tissues. We sequenced the alleles coding for three main variants, numbered according to the increase of the electrophoretic mobility. Allele 1 differs from the most common allele 2 by eight nucleotide substitutions, two of them associated with amino acid replacements, His->Tyr in the globular domain and Ala->Val in the C-terminal domain. Allele 3 differs from alleles 1 and 2 by a 24-bp deletion in the part coding for the C-terminal domain. In three greenhouse experiments, we compared quantitative traits in nearly isogenic lines differing by these H1-7 variants. In experiment 1, three lines bearing either of the three allelic variants were compared, the other experiments involved pairs of lines bearing variants 1 and 3. In all experiments, statistically significant differences between the lines were registered, mostly related to the plant size. The most prominent effect was associated with plant growth dynamics. Plants of line 3, carrying the 8-amino acid deletion in histone H1-7, on average grew slower. In two experiments, the differences of the mean stem length persisted throughout plant growth while in experiment 2 differences disappeared upon maturity. The H1-7 subtype is supposed to be related to maintenance of chromatin state characteristic for cell growth and division.

Nonconcerted evolution of histone 3 genes in a liverwort, Conocephalum conicum

To estimate the extent of genetic variation at the DNA level, the histone 3 (H3) genes were sequenced from single individual each from the three cryptic species recognized based on allozyme analyses, YFS, J and T types of Conocephalum conicum and two closely related species, C. japonicum and Marchantia polymorpha. Although the H3 genes are known to be highly conserved, the nucleotide diversities were 0.128, 0.109, 0.108, 0.049 and 0.034. These values are 30 to 100 times higher than that in Drosophila melanogaster (0.001). Besides, there were considerable differences in the position, length and number of introns among the loci of H3 genes. The observed high level of nucleotide diversities was explained by the fixation of many random mutations, and non-concerted evolution that resulted from low rates of unequal crossing-over and gene conversion probably due to the dispersed structure of H3 genes on genome in this species. The non-concerted evolutionary pattern was established by the analysis of phylogenetic tree and divergence rates. This study confirmed previous results suggesting that natural populations of liverwort maintains high extent of variation at DNA level.

Structure of allelic variants of subtype 5 of histone H1 in pea Pisum sativum L

The pea genome contains seven histone H1 genes encoding different subtypes. Previously, the DNA sequence of only one gene, His1, coding for the subtype H1-1, had been identified. We isolated a histone H1 allele from a pea genomic DNA library. Data from the electrophoretic mobility of the pea H1 subtypes and their N-bromosuccinimide cleavage products indicated that the newly isolated gene corresponded to the H1-5 subtype encoded by His5. We confirmed this result by sequencing the gene from three pea lines with H1-5 allelic variants of altered electrophoretic mobility. The allele of the slow H1-5 variant differed from the standard allele by a nucleotide substitution that caused the replacement of the positively charged lysine with asparagine in the DNA-interacting domain of the histone molecule. A temperature-related occurrence had previously been demonstrated for this H1-5 variant in a study on a worldwide collection of pea germplasm. The variant tended to occur at higher frequencies in geographic regions with a cold climate. The fast allelic variant of H1-5 displayed a deletion resulting in the loss of a duplicated pentapeptide in the C-terminal domain.

Evolution of the regular zone of histone H1 in fabaceae plants

An analysis of the histone H1 subtype, H1-1, in eight legumes belonging to four genera of the tribe Vicieae (Pisum, Lathyrus, Lens, and Vicia), revealed an extended region consisting of the tandemly repeated AKPAAK motifs. We named this region the Regular zone (RZ). The AKPAAK motifs are organized into two blocks separated by a short (two or six amino acids) intervening sequence (IS). The distal block contains six AKPAAK motifs, while the number of repeats in the proximal block varies from six in V. faba to seven in the other species. In V. hirsuta, the first two repeated units of the proximal block are octapeptides AKAKPAAK. The apparent rate of synonymous substitutions in the blocks of RZ is much higher than in the rest of the gene. This can be explained by repeat shuffling within each block. In the C-domain of the orthologous H1 subtype from Medicago truncatula (tribe Trifolieae), a region corresponding to the RZ of Vicieae species was found. It also consists of two blocks of AKPAAK motifs (four and three repeats in the proximal and distal blocks, respectively). These blocks are separated by a 20-amino acid IS. The first 20 amino acids of the Medicago RZ are not part of AKPAAK repeats. We hypothesise that the RZ has most probably evolved as a result of an expansion of AKPAAK repeats from two separate sites in the C-domain. This process started tens of millions of years ago and was most likely directed by positive selection.

A novel HMG A-like protein binds differentially to the AT-rich regions located in the far distal and proximal parts of a soybean glutamine synthetase gene (GS15) promoter

In soybean (Glycine max L.) ammonium provided externally or as the result of symbiotic nitrogen fixation stimulates the transcription of GS15, a gene encoding cytosolic glutamine synthetase. Strong constitutive positive expression (SCPE), silencer-like and organ-specific elements, located respectively in the distal, the central and the proximal region of the promoter are required to control the ammonium responsiveness of the gene expression [Tercé-Laforgue et al. (1999) Plant Mol. Biol. 39: 551]. It was hypothesized that the correct spatial conformation of the promoter permitted the cooperative action of these three cis-acting elements. Further investigations were therefore required to ascertain this hypothesis. A nodule nuclear protein, binding to a 66 bp AT-rich DNA fragment containing a 13 bp AT-rich repeated sequence (AT-1) and located just downstream of the SCPE element, was identified using a gel retardation assay. A cDNA clone likely to code for this protein was isolated using the yeast one-hybrid system. It encodes a novel DNA binding protein (AT-1SNBP) similar to HMG A proteins but exhibiting a higher molecular weight. AT-1SNBP appears to be encoded by a single gene that is expressed in roots, root nodules and leaves of soybean. Since two other 13 bp AT-rich repeated sequences (AT-2 and AT-3) were localized in the organ-specific element, we have quantified the binding affinity of AT-1SNBP to these sequences. We demonstrate that AT-1SNBP binds differentially to DNA fragments containing AT-1, AT-2 and AT-3 and that its binding affinity depends on the presence of adjacent sequences. This result suggests that AT-1SNBP may be an architectural protein involved in maintaining the spatial conformation of the GS15 promoter, thus facilitating the interaction between the distal and proximal regulatory elements.

Analysis of lysine-rich histones from the unicellular green alga Chlamydomonas reinhardtii

The H1 histones of the unicellular green alga Chlamydomonas reinhardtii were extracted from isolated nuclei, fractionated by high performance liquid chromatography, and analyzed by two-dimensional electrophoresis, peptide mapping, and N-terminal sequencing. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of 5% perchloric acid extracts of isolated C. reinhardtii nuclei revealed two H1 proteins (H1A and H1B). Two-dimensional gel analysis did not reveal heterogeneity of either algal H1 protein, but did detect differences in the hydrophobic amino acid content of the C. reinhardtii H1A and H1B. Digestion of H1A and H1B with V8 protease revealed two distinctly different peptide maps. C. reinhardtii H1 peptide maps were not at all similar to those of Pisum H1, but algal and pea H2B peptide maps did show some peptides in common. Seventeen amino acid residues were obtained from C. reinhardtii H1A amino terminal sequencing, while the H1B N-terminus was blocked. A search of protein data bases revealed no sequence homology of the H1A N-terminus with any known protein. Chlamydomonas histones fractionated by high performance liquid chromatography revealed minor components (histone variants) for H2A and H2B. The amino acid composition of Chlamydomonas lysine-rich histones was compared to those of various other unicellular algae.

Plant chromosomal HMGI/Y proteins and histone H1 exhibit a protein domain of common origin

The chromosomal high-mobility-group (HMG) proteins of the HMGI/Y family interact with A/T-rich stretches in duplex DNA, and are considered assistant factors in transcriptional regulation. A cDNA encoding an HMGI/Y protein of 190 amino acid residues was isolated from maize and characterized. Like other plant HMGI/Y proteins, the maize HMGI/Y protein contains four copies of the AT-hook DNA-binding motif and an amino-terminal 'histone H1-like region' with a similarity to the globular domain of H1. The maize hmgi/y gene that was isolated from a genomic DNA library contains a single intron that is localized in the region of sequence similarity to histone H1. Interestingly, the genes encoding plant H1 contain an intron at exactly the same relative position, indicating an evolutionary relationship of the plant genes encoding HMGI/Y and H1 proteins.

The biochemical and phenotypic characterization of Hho1p, the putative linker histone H1 of Saccharomyces cerevisiae

There is currently no published report on the isolation and definitive identification of histone H1 in Saccharomyces cerevisiae. It was, however, recently shown that the yeast HHO1 gene codes for a predicted protein homologous to H1 of higher eukaryotes (Landsman, D. (1996) Trends Biochem. Sci. 21, 287-288; Ushinsky, S. C., Bussey, H. , Ahmed, A. A., Wang, Y., Friesen, J., Williams, B. A., and Storms, R. K. (1997) Yeast 13, 151-161), although there is no biochemical evidence that shows that Hho1p is, indeed, yeast histone H1. We showed that purified recombinant Hho1p (rHho1p) has electrophoretic and chromatographic properties similar to linker histones. The protein forms a stable ternary complex with a reconstituted core di-nucleosome in vitro at molar rHho1p:core ratios up to 1. Reconstitution of rHho1p with H1-stripped chromatin confers a kinetic pause at approximately 168 base pairs in the micrococcal nuclease digestion pattern of the chromatin. These results strongly suggest that Hho1p is a bona fide linker histone. We deleted the HHO1 gene and showed that the strain is viable and has no growth or mating defects. Hho1p is not required for telomeric silencing, basal transcriptional repression, or efficient sporulation. Unlike core histone mutations, a hho1Delta strain does not exhibit a Sin or Spt phenotype. The absence of Hho1p does not lead to a change in the nucleosome repeat length of bulk chromatin nor to differences in the in vivo micrococcal nuclease cleavage sites in individual genes as detected by primer extension mapping.

Novel members of a family of AT hook-containing DNA-binding proteins from rice are identified through their in vitro interaction with consensus target sites of plant and animal homeodomain proteins

The AT hook is an AT-rich DNA-binding domain that occurs three times in mammalian high-mobility-group I/Y chromosomal proteins and has recently also been identified in DNA-binding proteins from plants. We unexpectedly isolated three rice cDNA clones encoding AT hook-containing proteins in an attempt to isolate homeobox cDNA clones by south-western screening of an expression library with known binding sites for Arabidopsis and animal homeodomain proteins. One of these clones (Os-PF1) has previously been identified due to the binding of its encoded protein to PE1, a cis-acting element from the oat phytochrome promoter. The other two clones represent newly described cDNA clones, designated Os-AT1 and Os-AT2. The Os-AT1 and Os-AT2 proteins were found to have the same specificities as Os-PF1 with respect to in vitro binding of wild-type and mutant PE1 versions. However, all three proteins appeared to bind much stronger in south-western assays to two of the rather AT-rich sequences used in our screening than to the PE1 element. In none of the AT hook proteins clear homologies to transcriptional activation domains could be identified, but the N-terminal regions of Os-AT1 and Os-PF1 were found to show similarity to histone H1 chromosomal proteins. Given their structural characteristics it is conceivable that the rice AT hook proteins bind to gene promoter regions as accessory proteins that may alter the accessibility of chromatin to other nuclear factors. Their predominant expression in young and meristematic tissues suggests that the presence of the AT hook proteins may affect the expression of genes that determine the differentiation status of cells.

Structure and characterization of a putative drought-inducible H1 histone gene

A drought- and abscisic acid (ABA)-inducible gene, His1, was isolated from Lycopersicon pennellii, a drought-resistant relative of cultivated tomato, and the gene structure was defined experimentally. The nucleotide sequence of His1 predicts a protein of 202 amino acid residues, with a significant sequence homology to plant H1 histones. Consensus sequences for both H1 histone-specific promoter elements as well as an ABA-responsive element were identified in the 5'-flanking region of His1. Transcripts of this gene accumulate in leaf tissue in response to drought in three tomato species including cultivated tomato (L. esculentum), L. pennellii, and L. chilense, as well as in tobacco. Transcripts for His1 are constitutively expressed in roots; transcript abundances in tomato root tips were equivalent to transcript abundances in more mature regions of the seedling root. The accumulation in leaves of transcripts for His1 preceded visible symptoms of drought stress in the plants. Transcript accumulation was detected in both drought-sensitive and drought-resistant species at similar leaf water potentials, psi W -1.3 to -1.4 MPa.

Molecular cloning and expression of mRNAs encoding H1 histone and an H1 histone-like sequences in root tips of pea (Psium sativum L.)

Two cDNA clones representing mRNAs, highly expressed in pea root tips, were isolated by mRNA differential display. Ribonuclease protection analyses showed different patterns of expression of these two messages in several pea tissues. Sequence analysis showed that the first clone, PsH1b-40, has 100% homology with a previously isolated H1 histone cDNA, PsH1b. However, it has an additional 30 nt at the 3' end which is absent in PsH1b, suggesting possible multiple polyadenylation sites in the same mRNA. The second clone, PsH1b-41, encodes a deduced 19.5 kDa protein of 185 amino acids with an isoelectric point of 11.5. The putative globular domain of the encoded protein showed 67-71% residue identity with globular domains of 28 kDa pea PsH1b H1 histone and Arabidopsis thaliana H1-1 H1 histone. It has 9 repeating motifs of (T/S)XXK. In the C-terminal domain, there are four lysine-rich repeating motifs of SXK(T/S)PXKKXK which may be involved in chromatin condensation and decondensation. Southern blot analysis of nuclear DNA shows that PsH1-41 belongs to a multigene family.

Structural and functional characterization of two wheat histone H2B promoters

Two wheat histone H2B genes (TH123 and TH153) were isolated. Nucleotide sequence analysis revealed that some characteristic sequence motifs were conserved in both the 5'- and 3'-flanking regions. A canonical TATA box and several CCAAT sequences were present in the presumed promoter regions. Motifs similar or identical to the hexamer (ACGTCA) and octamer (CGCGGATC) motifs that are positive cis-acting elements of the wheat H3 (TH012) promoter were also observed in both the H2B promoters. A gel mobility shift assay indicated that the hexamer and hexamer-like motifs bound the wheat bZIP proteins HBP-1a and/or HBP-1b in vitro. A novel sequence motif, (A/T)(G/A)AAAT(A/G), was found downstream of a translational stop codon as observed in several plant histone H2B cDNAs. Promoter activity was analyzed with H2B promoter-GUS fusion genes in the transient system using tobacco protoplasts. Studies of the promoter function in transgenic tobacco plants showed that the H2B promoters were preferentially active in meristematic tissues. Taken together, our data indicate that the H2B genes are regulated, in part, by the same mechanism as found in H3 and H4 gene transcription.

Molecular characterization and expression of a tobacco histone H1 cDNA

We have isolated a 1104 bp tobacco cDNA clone (H1c12) which includes an 846 bp open reading frame. This encodes a polypeptide of 282 amino acid residues and represents the largest plant H1 histone identified so far. The structure of the deduced protein shows the classical tripartite organization of the H1-type linker histones. The expression of the tobacco H1 histone gene(s) corresponding to the H1c12 cDNA clone was examined during different developmental stages. We found that, at the level of steady-state mRNA, expression of gene(s) encoding this H1 histone was rapidly induced in germinating seeds. The H1 gene was expressed in all tissues examined. However, its expression was higher in tissues known to contain meristematic cells. Furthermore, in the leaves of mature plants accumulation of the H1 mRNA exhibits a very characteristic oscillation. This latter finding indicates that, at least in fully developed plants, the expression of this type of H1 histone gene(s) is modulated by a diurnal cycle.

Molecular cloning, sequence analysis and differential expression of an intron-containing gene encoding tomato histone H1

A tomato genomic clone has been identified which encodes histone H1. The deduced polypeptide is 287 amino acids in length, and exhibits the tripartite organization typical of histones H1. The central globular domain is highly similar to those regions from other H1 molecules, and the carboxyl-terminal domain contains a repeating hexapeptide motif, variants of which are conserved among H1 molecules. RNA gel blotting revealed that histone H1 mRNA is expressed at higher levels in organs which contain meristematic tissue and/or which have a high proportion of actively cycling cells. DNA gel blotting and dot-blot hybridization studies revealed that histone H1 in tomato is encoded by a small gene family. By employing the polymerase chain reaction on genomic DNA and on cDNA, it was determined that the gene is interrupted by an intron. The location and approximate length of the intron are conserved in both the tomato and Arabidopsis genes, with the intron separating the 'nose' region (encoded by exon 1) from the central globular domain (exon 2). The promoter region was found to contain several conserved sequence motifs which likely participate in the regulation of the gene.

Molecular cloning of cDNAs encoding variants of meiotin-1. A meiotic protein associated with strings of nucleosomes

Meiotin-1 is a chromatin-associated protein, originally isolated from microsporocytes of Lilium longiflorum, which is found predominantly in cells undergoing meiotic prophase. Chromatin fractionation studies demonstrated that meiotin-1 has an unusual stoichiometry relative to that of histone H1 and the core histones in chromatin fibers. The protein is found less frequently than is histone H1, and appears to be distributed once every 5 to 13 nucleosomes. This distribution may approximate the number of nucleosomes per turn of the chromatin solenoid. A truncated cDNA was identified by immunoscreening of an expression library, and the cDNA was used as a hybridization probe to select a full length cDNA. Variations between the sequence of the predicted polypeptide and sequenced peptides, and variations between the amino acid composition of the protein and the deduced protein indicate that the cDNAs encode minor variants of mature meiotin-1. RNA gel blot hybridization studies reveal that the meiotin-1 mRNA is restricted to anthers in which meiosis is occurring. Computer analysis of the polypeptide deduced from the cDNA indicates that the protein begins with a region highly homologous to the conserved central globular domain of histone H1 molecules. DNA gel blotting experiments demonstrate that homologous sequences exist in the genomes of a fern, a fungus, and both mono- and dicotyledonous plants. Meiotin-1 has been evolutionarily conserved and I propose that it arose from histone H1 to fulfill a role in organizing meiotic chromatin.

Two histone H1-encoding genes of the green alga Volvox carteri with features intermediate between plant and animal genes

Southern hybridization indicated the presence of at least two and possibly four histone H1-encoding genes occurring as singlets in the Volvox carteri genome. Two of these genes, H1-I and H1-II, have been cloned and characterized. Their coding sequences are each interrupted by three introns, but only the position of the second intron is identically conserved in both H1-I and H1-II. The encoded 260-amino-acid (aa) (H1-I) and 240-aa (H1-II) polypeptides possess the typical tripartite organization of animal H1 histones, with variable N- and C-terminal domains flanking a conserved 'globular' DNA-binding domain. Extensive differences in their variable regions suggest that H1-I and H1-II (62% identity) represent two isotypes with different functions. A prominent KAPKAP-KAA motif in the H1-I N-terminal region, similarly seen in single H1 variants of a mosquito and a nematode, has a putative function in packing condensed subtypes of chromatin. Different from higher plants, but like animals, the H1 genes of V. carteri possess a typical 3' palindrome for mRNA processing, resulting in non-polyadenylated mRNAs. Transcription initiates 33 nucleotides (nt) (H1-I) and 26 nt (H1-II) downstream of typical TATA boxes. A putative 20-bp conserved enhancer element upstream of each TATA box closely resembles the consensus sequence associated with the nucleosomal histone-encoding genes in V. carteri [Müller et al., Gene 93 (1990) 167-175] and suggests stringent regulation. Accordingly, transcription of H1 was shown to be restricted to late embryogenesis, when new flagella are produced. We discuss the inferred accessory role of histone H1 proteins in stabilizing axonemal microtubules, as has been recently observed in sea urchin flagella [Multigner et al., Nature 360 (1992) 33-39].

cDNA sequence and expression of an intron-containing histone H2A gene from Norway spruce, Picea abies

We have isolated a cDNA clone corresponding to a histone H2A gene from Norway spruce, Picea abies (L.) Karst. The clone was isolated on the basis of the preferential expression of the corresponding gene during germination. The identification of the clone was based on the high degree of nucleotide sequence identity (60-65%) to a range of eukaryotic histone H2A genes and the presence of a 9 amino acids long sequence identical to the conserved 'H2A box' in the deduced amino acid sequence. Like other plant histone genes, the spruce histone H2A gene encodes a polyadenylated transcript. Further, the spruce gene contains an intervening sequence of 891 bp in the coding region. The presence of introns is typical of a distinct class of replication-independent histone genes in other eukaryotes. However, the sequence of the spruce gene and its high expression in mitotically active tissues such as the apical meristem, strongly suggests that it belongs to the class of replication-dependent histone genes. This is the first documentation of an intervening sequence in this class of histone genes and the finding implies that introns were present in the ancestral histone H2A gene before the divergence of the two classes of histone genes.

Histones and histone genes in higher plants: structure and genomic organization

The primary structure of the plant histone genes has been deduced from the comparison of the nucleotide sequences of 23 genes and 14 cDNAs from eight different species. These data confirmed the extreme conservation of histones H3 and H4 in plant and animal kingdoms. Histone H2B is more variable than H2A and the histone H1 is the less conserved histone. Some interesting observations concerning the non-conserved regions of H2A and H2B in their extended C- and N-terminal regions are reported. Only three plant histone genes were found to possess intervening sequences: one H1 gene and two H3.3 like genes. The most striking differences found between the two kingdoms are the absence from plant histone genes of the palindromic structure existing downstream of the animal genes and the fact that plant histone mRNAs are polyadenylated. This suggests that the post-transcriptional regulation of expression of histone genes is different in the two kingdoms. In plants the multiple copies of the histone genes are organized into multigenic families. In the complex genome of maize the multiple copies of the genes are highly dispersed on the genome.

Arabidopsis thaliana H1 histones. Analysis of two members of a small gene family

We have isolated two Arabidopsis thaliana cDNA clones that encodes different H1 histone proteins. The H1-1 and H1-2 proteins are 274 and 273 amino acids in length, respectively. Unlike the H1 histones within a single animal species, the two plant H1 proteins share little sequence similarity outside the protein's central globular domain. Within the globular domain, a pentapeptide that is extremely well conserved in animal H1 histones, is not found in either of the plant proteins. Southern blot analysis suggests that A. thaliana has only three H1 histone genes. A genomic clone encoding the H1-1 protein was isolated and the protein-coding region was found to consist of two exons separated by a 104-bp intron. The site of transcriptional initiation of the H1-1 gene was mapped by primer-extension analysis and a conserved octamer motif, identical to that observed in most plant core histone genes that have been characterized to date, was found 101 nucleotides upstream of the presumed transcription-initiation site. The 3' portion of the gene encoding H1-2 was also isolated and sequenced. When the 3'-flanking regions of the two H1 genes were compared, several highly conserved sequences were observed that might be convergently transcribed relative to the histone genes.

Antibodies directed against a meiosis-specific, chromatin-associated protein identify conserved meiotic epitopes

The molecular mechanisms by which meiotic events are regulated are at present unknown. To approach this problem, we have exploited the natural synchrony of Lilium meiocytes to compare the nuclear protein profiles of a variety of stages of meiosis. This approach has facilitated the identification of a number of nuclear proteins that appear and disappear in a stage-specific fashion. Here we report the presence of an abundant nuclear protein that first appears during premeiotic interphase, a period during which the irreversible commitment to meiosis occurs. Antibodies directed against this protein demonstrate its meiosis specificity as well as conservation of the epitope(s) in both mono- and dicotyledonous plant species. Chromatin fractionation studies indicate that this protein, which we have termed meiotin-1, is associated with strings of nucleosomes. Implications for meiotic chromatin packaging and chromosome structure are discussed.

Nucleotide sequence and expression of a maize H1 histone cDNA

The first complete amino acid sequence of a H1 histone of a monocotyledonous plant was deduced from a cDNA isolated from a maize library. The encoded H1 protein is 245 amino acid-long and shows the classical tripartite organization of this class of histones. The central globular region of 76 residues shows 60% sequence homology with H1 proteins from dicots but only 20% with the animal H1 proteins. However, several of the amino acids considered as being important in the structure of the nucleosome are conserved between this protein and its animal counterparts. The N-terminal region contains an equal number of acidic and basic residues which appears as a general feature of plant H1 proteins. The 124 residue long and highly basic C-terminal region contains a 7-fold repeated element KA/PKXA/PAKA/PK. Southern-blot hybridization showed that the H1 protein is encoded by a small multigene family. Highly homologous H1 gene families were also detected in the genomes of several more or less closely related plant species. The general expression pattern of these genes was not significantly different from that of these genes encoding the core-histones neither during germination nor in the different tissues of adult maize.

Analysis of the charge distribution in the C-terminal region of histone H1 as related to its interaction with DNA

We have studied the net positive charge distribution in the C-terminal region of histone H1. We find that it is not random, but rather uniform. In most histone H1 sequences, 4 +/- 1 positive charges are found in this region of the molecule in over 95% of all possible segments that are 10 amino acids long. Neither alternating sequences (basic-nonbasic) nor more complex repeating sequences are ever found. Clusters of three or more basic amino acids are seldom observed in somatic H1s, yet their presence increases in sperm histones and even more so in protamines. It is concluded that the C-terminal region of histone H1 has a remarkably uniform distribution of charge, in spite of its apparent variations in sequence in different proteins and within individual molecules. The functional significance of these findings is discussed, suggesting a purely electrostatic role for the C-terminal region of histone H1, which may be evenly wrapped around individual segments of DNA molecules, thus decreasing its net charge. A likely candidate for a long alpha-helical region in the C-terminal region of histone H1 from sea urchin spermatozoa also has been located. This region may contribute to the aggregating properties of this histone in sperm chromatin.

Chromatin superstructure-dependent crosslinking with DNA of the histone H5 residues Thr1, His25 and His62

The points of histone H5 interactions with DNA within nucleosomes and chromatin at different levels of compaction are delineated by identification of H5 amino acid residues that can be covalently bound to DNA. Three major crosslinkable points of H5 are His25, His62 (both within the globular part of the molecule), and N-terminal Thr1. His25 interacts with the terminal regions of nucleosomal DNA; His62 appears to bind more distal segments of the linker DNA. The His25-DNA crosslink predominates in the isolated mononucleosomes and persists throughout the chromatin condensation states studied, from extended oligonucleosomal chains to nuclei. His62 is the strongest crosslinking site in nuclei; in oligonucleosomes, the predominance of the His62-DNA crosslink requires the number of nucleosomes in the chain to be above some critical value. The Thr1-DNA crosslink is generated only in decondensed poly- or oligonucleosomes, but not in mononucleosomes. Thus, underlying the higher-order folding transitions of the nucleosomal chain is the restructuring of H5-DNA interactions.

Polyadenylated H3 histone transcripts and H3 histone variants in alfalfa

Histone H3 mRNAs were found in polyA(+) fractions of total RNA prepared from alfalfa plants, calli and somatic embryos. The sequence analysis of cDNAs revealed the presence of a polyA tail on independent alfalfa H3 mRNAs. A highly conserved sequence motif AAUGAAA identified about 20bp upstream from the 3' ends of the alfalfa H3 cDNAs was suggested to be one of the possible regulatory elements in the 3' end formation and polyadenylation. Three out of the four analysed H3 cDNAs have more than 97% homology with a genomic clone and encode the same protein. While the fourth represents a minor species with only 78.8% homology to the coding region of the genomic clone and encodes a H3 histone with four amino acid replacements. On the basis of compilation analysis we suggest a consensus sequence for plant H3 histones which differs from that of animal's by four amino acid changes.

The phosphorylation site of Ca(2+)-dependent protein kinase from alfalfa

A 50 kDa, calcium-dependent protein kinase (CDPK) was purified about 1000-fold from cultured cells of alfalfa (Medicago varia) on the basis of its histone H1 phosphorylation activity. The major polypeptide from bovine histone H1 phosphorylated by either animal protein kinase C (PK-C) or by the alfalfa CDPK gave an identical phosphopeptide pattern. The phosphoamino acid determination showed phosphorylation of serine residues in histone H1 by the plant enzyme. Histone-related oligopeptides known to be substrates for animal histone kinases also served as substrates for the alfalfa kinase. Both of the studied peptides (GKKRKRSRKA; AAASFKAKK) inhibited phosphorylation of H1 histones by bovine and alfalfa kinases. The results of competition studies with the nonapeptide (AAASFKAKK), which is a PK-C specific substrate, suggest common features in target recognition between the plant Ca(2+)-dependent kinase and animal protein kinase C. We also propose that synthetic peptides like AAASFKAKK can be used as a tool to study substrates of plant kinases in crude cell extracts.

Codon usage in plant genes

We have examined codon bias in 207 plant gene sequences collected from Genbank and the literature. When this sample was further divided into 53 monocot and 154 dicot genes, the pattern of relative use of synonymous codons was shown to differ between these taxonomic groups, primarily in the use of G + C in the degenerate third base. Maize and soybean codon bias were examined separately and followed the monocot and dicot codon usage patterns respectively. Codon preference in ribulose 1,5 bisphosphate and chlorophyll a/b binding protein, two of the most abundant proteins in leaves was investigated. These highly expressed are more restricted in their codon usage than plant genes in general.

Conserved epitopes on plant H1 histones recognized by monoclonal antibodies

A series of monoclonal antibodies specific for distinct regions of H1 histone from the plant Nicotiana tabacum were obtained from fusion experiments with spleen cells of mice immunized with tobacco nuclear extracts. These monoclonal antibodies were characterized and the evolutionary conservation of the epitopes in higher plants and animals studied by immunoblotting and enzyme-linked immunosorbent assay (ELISA). Whereas some epitopes appear restricted to the Solanaceae plant family, others are common to all higher eukaryotes tested and even detectable on nuclear proteins of yeast. ELISA experiments performed with isolated tobacco chromatin give some indications of the differential accessibility of the epitopes after interaction of H1 histone with the nucleosome.

Polyadenylation of histone H3 and H4 mRNAs in dicotyledonous plants

The histone H3 and H4 genes are shown to be expressed in both Arabidopsis plantlets and transitory multicellular suspension. The 5'- and 3'-ends of the H4 mRNAs have been localized on two H4 genes previously sequenced, H4A748 and H4A777. S1-nuclease mapping and reverse-transcriptase-primer-elongation experiments revealed the existence of two start points for transcription, located 31 and 37 nucleotides downstream from the TATA-box. The 3'-end of the mRNA corresponding to H4A748 was localized at 177 nt after the stop codon. The other gene, H4A777, most probably is not expressed. In addition to a long 3'-untranslated region, the H4 mRNA was shown to be polyadenylated in both plantlets and cell-suspension. This observation was extended to the H3 mRNAs of Arabidopsis and of two other dicots, tobacco and sunflower. Previous results on maize H3 and H4 mRNAs suggest that polyadenylation is a common feature for histone mRNAs in higher plants.

Nucleotide sequences of cDNAs encoding four complete nuclear-encoded plastid ribosomal proteins

The nucleotide sequences of four pea nuclear-encoded plastid ribosomal protein cDNAs have been determined. These cDNAs were shown to encode the complete precursor proteins. The transit sequences of the encoded proteins are similar to the transit sequences of other imported proteins being rich in serine and/or threonine and lacking aspartic and glutamic acid. The transit sequences do not, however, have any apparent amino acid sequence similarity with one another or with the transit sequences of other imported proteins. The derived amino acid sequences of the plastid ribosomal proteins were compared to the amino acid sequences of other ribosomal proteins. Significant amino acid sequence similarity was found between Escherichia coli ribosomal proteins L9 and L24 and two of the nuclear-encoded pea plastid ribosomal proteins.

Expression of a histone H1-like protein is restricted to early Xenopus development

Genes whose expression is restricted to oogenesis and early development may have important functions in these processes. Northern analysis showed that Xenopus B4 mRNA is expressed in oogenesis and embryogenesis through to the neurula stage. Immunocytochemistry with anti-B4 antibodies showed that B4 protein is only detectable in preneurula stages; it is localized to nuclei and is associated with metaphase chromosomes. Immunoblotting revealed approximately constant levels of B4 protein per embryo for the first 2 days of development. Thus, as the number of nuclei increases during early development, the amount of B4 protein per nucleus is diluted out. Sequencing of two B4 cDNA clones revealed that the predicted B4 translation product is a 29-kD protein with 29% identity with histone H1, distributed over the entire length of its sequence. The B4 protein also has certain other H1 protein characteristics--a tripartite structure consisting of a mainly hydrophobic central domain flanked by an amino-terminal segment and a long hydrophilic carboxyterminal tail containing a tandemly repeated amino acid motif. However, in contrast to histone H1 mRNA, B4 mRNA has a classic polyadenylation signal, is polyadenylated, and lacks the histone H1 3' noncoding consensus sequence involved in RNA processing.

Isolation of an alfalfa histone H3 gene: structure and expression

A histone H3 gene was isolated from a dicotyledonous plant, alfalfa (Medicago sativa). The sequence analysis of this gene revealed no obvious GC preference in its codon usage. Apart from containing most of the typical consensus sequences found in both animal and plant histone genes, the alfalfa H3 gene exhibits distinct structural features such as (1) the unusual location of two GATCC motifs in its 5' flanking sequence, (2) the existence of a CGCGGATC on the nonsense strand at position -232, (3) the existence of a long palindromic structure, and (4) several polyadenylation signal-like sequences in the 3' flanking region. There are about 160 copies of histone H3 gene in alfalfa tetraploid genome.Using the alfalfa H3 gene as a probe to study the pattern of histone H3 transcripts in the alfalfa, we found that the H3 RNAs are undetectable in leaves, more in stems than in roots, and highest in somatic embryos. Moreover, the RNA products of H3 genes in all alfalfa tissues tested show unusually long nontranslated region compared to those of animal histone genes. An additional high molecular weight species of H3 transcript was detected only in somatic embryos.

The histone H3 and H4 mRNAs are polyadenylated in maize

Northern blot analysis revealed that the histone H3 and H4 mRNAs are of unusual large size in germinating maize embryos. S1-mapping experiments show that the 3'-untranslated regions of the mRNAs transcribed from 3 H3 and 2 H4 maize genes previously described are much longer than in the non-polyadenylated histone mRNAs which represent a major class in animals. Moreover, oligo d(T) cellulose fractionation of RNAs isolated at different developmental stages indicates that more than 99% of the maize H3 and H4 mRNAs are polyadenylated. A putative polyadenylation signal is present in all five genes 17 to 27 nucleotides before the 3'-ends of the mRNAs.