Organization and bidirectional transcription of H2A, H2B and H4 histone genes in rice embryos

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.

Plant molecular biology and biotechnology research in the post-recombinant DNA era

After the beginning of the recombinant DNA era in the mid-1970s, researchers in India started to make use of the new technology to understand the structure of plant genes and regulation of their expression. The outcome started to appear in print in early the 1980s and genes for histones, tubulin, photosynthetic membrane proteins, phototransduction components, organelles and those regulated differentially by developmental and extrinsic signals were sequenced and characterized. Some genes of biotechnological importance like those encoding an interesting seed protein and the enzyme glyoxalase were also isolated. While work on the characterization of genome structure and organization was started quite early, it remained largely focused on the identification of DNA markers and genetic variability. In this context, the work on mustard, rice and wheat is worth mentioning. In the year 2000, India became a member of the international consortium to sequence entire rice genome. Several laboratories have also given attention to regulated expression of plastid and nuclear genes as well as to isolate target-specific promoters or design promoters with improved potential. Simultaneously, transgenic systems for crops like mustard, rice, wheat, cotton, legumes and several vegetables have been established. More recently, genes of agronomic importance like those for insect resistance, abiotic stress tolerance, nutritional improvement and male sterility, isolated in India or abroad, have been utilized for raising transgenics for crop improvement. Some of these transgenics have already shown their potential in containment facility or limited field trials conducted under the stipulated guidelines. Plant molecular biology and biotechnology are thus clearly poised to make an impact on research in basic biology and agriculture in the near future.

Chromosomal locations of the genes for histones and a histone gene-binding protein family HBP-1 in common wheat

The chromosomal locations of the genes in common wheat that encode the five histones and five members of the HBP (histone gene-binding protein)-1 family were determined by hybridizing their cloned DNAs to genomic DNAs of nullitetrasomic and telosomic lines of common wheat, Triticum aestivum cv. Chinese Spring. The H1 and H2a genes are located on different sets of homoeologous chromosomes or chromosome arms, namely, 5A, 5B and 5D, and 2AS, 2BS and 2DS, respectively. Genes for the other histones, H2b, H3 and H4, are found in high copy number and are dispersed among a large number of chromosomes. The genes for all members of the HBP-1 family are present in small copy numbers. Those for HBP-1a(1) are located on six chromosome arms, 3BL, 5AL, 5DL, 6AL, 6BS and 7DL, whereas those for each HBP-1a(c14), 1a(17), 1b(c1), and 1b(c38) are on a single set of homoeologous chromosome arms; 4AS, 4BL, 4DL; 6AS, 6BS, 6DS; 3AL, 3BL, 3DL; and 3AS, 3BS, 3DS, respectively. The genes for histones H1 and H2a, and for all members of the HBP-1 family except HBP-1a(1) are assumed to have different phylogenetic origins. The genes for histone 2a and HBP-1a(17) are located in the RFLP maps of chromosomes 2B and 6A, respectively. Gene symbols are proposed for all genes whose chromosomal locations have been determined.

A wheat histone H3 promoter confers cell division-dependent and -independent expression of the gus A gene in transgenic rice plants

To investigate developmental regulation of wheat histone H3 gene expression, the H3 promoter, which has its upstream sequence to -1711 (relative to the cap site as +1), was fused to the coding region of the gus A gene (-1711H3/GUS) and introduced into a monocot plant, rice. Detailed histochemical analysis revealed two distinct types of GUS expression in transgenic rice plants; one is cell division-dependent found in the apical meristem of shoots and roots and in young leaves, and another is cell division-independent detected in flower tissues including the anther wall and the pistil. In this study, replication-dependent expression occurring in non-dividing cells which undergo endoreduplication could not be discriminated from strict replication-independent expression. The observed expression pattern in different parts of roots suggested that the level of the H3/GUS gene expression is well correlated with activity of cell division in roots. To identify 5' sequences of the H3 promoter necessary for an accurate regulation of the GUS expression, two constructs containing truncated promoters, -908H3/GUS and -185H3/GUS, were analyzed in transiently expressed protoplasts, stably transformed calli and transgenic plants. The results indicated that the region from -909 to -1711 contains the positive cis-acting element(s) and that the proximal promoter region (up to -185) containing the conserved hexamer, octamer and nonamer motifs is sufficient to direct both cell division-dependent and -independent expression. The use of the meristem of roots regenerated from transformed calli for the analysis of cell division-dependent expression of plant genes is discussed.

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.

Variability and inheritance of histone genes H3 and H4 in Vicia faba

We have compared copy numbers and blothybridization patterns of histone genes (H3 plus H4) between and within individuals of broad bean (Vicia faba). Copy number differences among individuals in the population of 200 individuals were as great as 27 fold, and as much as 3.2 fold among separate leaves of the same plant. Among F2 progeny from genetic crosses, up to a 5.4-fold range was seen (mean=3.5 fold), and among F1 progeny of self-pollinated plants, up to a 5.9-fold range was observed (mean=2.3 fold). Histone gene blot-hybridization patterns for EcoRI and HindIII were also variable among individuals and indicated that the genes are probably clustered in only a few chromosomal loci. The degree of variation in histone gene copy number per haploid genome (2-55 copies, or 27 fold) was similar to that found previously for ribosomal RNA genes (230-22000, or 95 fold) of V. faba. However, the two gene families change independently, since individuals with a high or low copy number for one gene can have either a high or low copy number for the other. The mechanisms(s) for rapid gene copy number change may be similar for these gene families.

Spatial patterns of histone mRNA expression during grain development and germination in rice

The pattern of distribution of histone H3 mRNA during the development of the rice grain and its germination was monitored by in situ hybridization and confirmed by Northern blot analysis. In ovaries sampled before and after fertilization, a 3H-labeled histone RNA probe was localized in the cells of the pericarp, outer integument and nucellus but binding of the probe decreased as these tissues senesced. In the developing embryo, the histone message was first detected in the scutellum; later, all parts of the embryo except the shoot apex, newly formed leaf primordia and the quiescent center of the root, revealed the presence of transcripts. Considerable binding of the probe also occurred in the endosperm as its cells began to accumulate starch. Cells of the embryo and endosperm of mature grains displayed very little or no histone mRNA, although during germination, these transcripts reappeared in the cells of both embryo and endosperm. There was a good correlation between the presence or absence of binding to the 32P-labeled histone gene DNA by RNA extracted from grains of different stages of development and germination, as revealed by Northern blot analysis and by spatial localization following in situ hybridization.

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.

Variable copy number DNA sequences in rice

We have cloned two types of variable copy number DNA sequences from the rice embryo genome. One of these sequences, which was cloned in pRB301, was amplified about 50-fold during callus formation and diminished in copy number to the embryonic level during regeneration. The other clone, named pRB401, showed the reciprocal pattern. The copy numbers of both sequences were changed even in the early developmental stage and eliminated from nuclear DNA along with growth of the plant. Sequencing analysis of the pRB301 insert revealed some open reading frames and direct repeat structures, but corresponding sequences were not identified in the EMBL and LASL DNA databases. Sequencing of the nuclear genomic fragment cloned in pRB401 revealed the presence of the 3'rps12-rps7 region of rice chloroplast DNA. Our observations suggest that during callus formation (dedifferentiation), regeneration and the growth process the copy numbers of some DNA sequences are variable and that nuclear integrated chloroplast DNA acts as a variable copy number sequence in the rice genome. Based on data showing a common sequence in mitochondria and chloroplast DNA of maize (Stern and Lonsdale 1982) and that the rps12 gene of tobacco chloroplast DNA is a divided gene (Torazawa et al. 1986), it is suggested that the sequence on the inverted repeat structure of chloroplast DNA may have the character of a movable genetic element.

Genomic organization and nucleotide sequences of two histone H3 and two histone H4 genes of Arabidopsis thaliana

Two histone H3 and two histone H4 genes have been cloned from a λgtWESλ·B Arabidopsis thaliana gene library. From their nucleotide sequences and from studies on their genomic organization, the following conclusions can be drawn: : 1) The nucleotide sequences of the two H3 coding regions show only 85% homology, but encode the same proteins. The Arabidopsis H3 has the same amino acid sequence as its counterpart in corn, but differs from that of pea and wheat by replacement in position 90 of a serine by an alanine. The two H4 coding regions have 97% sequence homology and encode the same protein, identical to the sequence of their counterpart in pea, corn and one H4 variant in wheat. 2) The 5'-flanking regions of the 4 genes contain the classical histone-gene-specific consensus sequences, except H3A725 which lacks the GATCC-like pentamer. The conserved octanucleotide 5'-CGCGGATC-3' which was previously found in the 5'-flanking sequences of corn and wheat H3 and H4 genes is also present in all four genes described here approximately 200 to 250 nucleotides upstream from the initiation ATG. The 5'-flanking regions of the H4 genes display extensive sequence homology, whereas those of the H3 genes do not. 3) The 3'-flanking regions do not possess the classical histone-gene-specific T hyphenated dyad symmetry motif. 4) Each H3 and H4 gene exists as 5 to 7 copies per haploid genome.

Nucleotide sequences of two corn histone H3 genes. Genomic organization of the corn histone H3 and H4 genes

Two histone H3 genes have been cloned from a λgtWESλ.B corn genomic library. The nucleotide sequences show 96% homology and both encode the same protein, which differs from its counterpart in wheat and pea by one amino acid substitution. The 5'-flanking regions of the two corn H3 genes contain the classical histone-gene-specific consensus sequences and possess several regions of extensive nucleotide homology. A conserved octanucleotide 5'-CGCGGATC-3' occurs at approximately 200 nucleotides upstream from the initiation ATG codon. This octanucleotide was found to exist in all of the 7 plant histone genes sequenced so far. Codon usage is characterized by a very high frequency of C (67%) and G (28%) at the third position of the codons, those ending by A (1%) and T (4%) being practically excluded.Comparison of Southern blots of EcoRI, EcoRV and BamHI digested genomic DNA suggests that the corn H3 and H4 genes are not closely associated. The H3 genes exist as 60 to 80 copies and the H4 genes as 100 to 120 copies per diploid genome. re]19851002 rv]19851212 ac]19851216.

Genomic organization and nucleotide sequences of two corn histone H4 genes

The sea urchin histone H4 gene has been used as a probe to clone two corn histone H4 genes from a lambda gtWES X lambda B corn genomic library. The nucleotide (nt) sequences of both genes showed that the encoded amino acid sequences were identical to that of the H4 of pea and one variant of wheat. The nt sequences of the coding regions showed 92% homology. 5'- and 3'-flanking regions do not show extensive nt sequence analogies. Southern blotting of the EcoRI digested genomic DNA suggests the existence of multiple H4 genes dispersed throughout the genome.