Nuclease hypersensitive sites in chromatin

Regulatory chromatin landscape in Arabidopsis thaliana roots uncovered by coupling INTACT and ATAC-seq

BACKGROUND

There is a growing interest in the role of chromatin in acquiring and maintaining cell identity. Despite the ever-growing availability of genome-wide gene expression data, understanding how transcription programs are established and regulated to define cell identity remains a puzzle. An important mechanism of gene regulation is the binding of transcription factors (TFs) to specific DNA sequence motifs across the genome. However, these sequences are hindered by the packaging of DNA to chromatin. Thus, the accessibility of these loci for TF binding is highly regulated and determines where and when TFs bind. We present a workflow for measuring chromatin accessibility in Arabidopsis thaliana and define organ-specific regulatory sites and binding motifs of TFs at these sites.

RESULTS

We coupled the recently described isolation of nuclei tagged in specific cell types (INTACT) and assay for transposase-accessible chromatin with high-throughput sequencing (ATAC-seq) as a genome-wide strategy to uncover accessible regulatory sites in Arabidopsis based on their accessibility to nuclease digestion. By applying this pipeline in Arabidopsis roots, we revealed 41,419 accessible sites, of which approximately half are found in gene promoters and contain the H3K4me3 active histone mark. The root-unique accessible sites from this group are enriched for root processes. Interestingly, most of the root-unique accessible sites are found in nongenic regions but are correlated with root-specific expression of distant genes. Importantly, these gene-distant sites are enriched for binding motifs of TFs important for root development as well as motifs for TFs that may play a role as novel transcriptional regulators in roots, suggesting that these accessible loci are functional novel gene-distant regulatory elements.

CONCLUSIONS

By coupling INTACT with ATAC-seq methods, we present a feasible pipeline to profile accessible chromatin in plants. We also introduce a rapid measure of the experiment quality. We find that chromatin accessibility at promoter regions is strongly associated with transcription and active histone marks. However, root-specific chromatin accessibility is primarily found at intergenic regions, suggesting their predominance in defining organ identity possibly via long-range chromatin interactions. This workflow can be rapidly applied to study the regulatory landscape in other cell types, plant species and conditions.

Regulation of immunoglobulin heavy-chain gene rearrangements

Regulated assembly of antigen receptor gene segments to produce functional genes is a hallmark of B- and T-lymphocyte development. The immunoglobulin heavy-chain (IgH) and T-cell receptor beta-chain genes rearrange first in B and T lineages, respectively. Both loci require two recombination events to assemble functional genes; D-to-J recombination occurs first followed by V-to-DJ recombination. Despite similarities in overall rearrangement patterns, each locus has unique regulatory features. Here, we review the characteristics of IgH gene rearrangements such as developmental timing, deletion versus inversion, DH gene segment utilization, ordered recombination of VH gene segments, and feedback inhibition of rearrangement in pre-B cells. We summarize chromatin structural features of the locus before and during recombination and, wherever possible, incorporate these into working hypotheses for understanding regulation of IgH gene recombination. The picture emerges that the IgH locus is activated in discrete, independently regulated domains. A domain encompassing DH and JH gene segments is activated first, within which recombination is initiated. VH genes are activated subsequently and, in part, by interleukin-7. These observations lead to a model for feedback inhibition of IgH rearrangements.

State of histone modification in the rat Ig-beta/growth hormone locus

The state of acetylation in H3 and H4 histones and dimethylation in the H3 histone Lys4 residue were examined by chromatin immunoprecipitation (ChIP) at 11 targets in the rat Ig-beta/growth hormone locus. Marked enhancement of the acetylation of histones H3 and H4 and the dimethylation of H3 Lys4 was observed in the chromatin situated close to the promoter of an actively transcribed gene. Chromatin positioned near a cell-type-specific DNase I-hypersensitive site with enhancer activity had the same histone modifications as the active promoter. In one transcribed intron, chromatin with fewer histone modifications was found, and in another transcribed intron, chromatin with markedly enhanced modifications was found. In most cases, no appreciable difference in the acetylation of histones H3 and H4 was found at prominently enhanced targets. However, different acetylation levels of H3 and H4 were found at one target. The targets with enhanced dimethylation of the H3 Lys4 residue coincided with those with prominently enhanced acetylation of histones H3 and H4.

Association of 5' CpG demethylation and altered chromatin structure in the promoter region with transcriptional activation of the multidrug resistance 1 gene in human cancer cells

Selection of human cells for resistance to vincristine or doxorubicin often induces overexpression of the multidrug resistance 1 gene (MDR1), which encodes the cell surface P-glycoprotein, as a result of gene amplification or transcriptional activation. However, the precise mechanism underlying such transcriptional activation of MDR1 remains unclear. The relation between methylation status of CpG sites in the MDR1 promoter region and transcriptional activation of MDR1 has now been investigated. The P-glycoprotein-overexpressing, multidrug-resistant KB/VJ300 and KB-C1 cells, which were established from human cancer KB3-1 cells, were examined; MDR1 is transcriptionally activated but not amplified in KB/VJ300 cells, whereas it is amplified in KB-C1 cells. Determination of the methylation status revealed that the MDR1 promoter region was hypomethylated in KB/VJ300 and KB-C1 cells, but hypermethylated in KB3-1 cells. Prior treatment of KB3-1 cells with the DNA methyltransferase inhibitor 5-aza-2'-deoxycytidine resulted in a 90-fold increase in the frequency of vincristine-resistance. Of three lines, KB/CdR-1, KB/CdR-2, and KB/CdR-3, established from KB3-1 cells after exposure to 5-aza-2'-deoxycytidine, MspI/HpaII sites in the MDR1 promoter region were hypomethylated in KB/CdR-1 and KB/CdR-2 cells, but not in KB/CdR-3 cells. MDR1 mRNA expression was detected in KB/CdR-1 and KB/CdR-2 cells, but not in KB/CdR-3 cells. The binding of YB-1 and Sp1, transcription factors implicated in MDR1 expression, in the MDR1 promoter was not affected by the methylation status of a neighboring CpG sites. The MDR1 promoter region in KB/VJ300 cells showed an increased sensitivity to DNase I compared with that in KB3-1 cells, suggesting an altered chromatin structure. The methylation status of the promoter region may plays an important role in MDR1 overexpression and in acquisition of the P-glycoprotein-mediated multidrug resistance phenotype.

Characterization of a chromatin remodelling activity in Xenopus oocytes

The yeast SWI2/SNF2 protein is a component of a large protein complex which is involved in the remodelling of chromatin during transcriptional activation. Several homologous complexes have been found in Drosophila and mammals. We have examined the expression of the SWI2/SNF2 homologue BRG1 in Xenopus laevis using two antisera originally raised against the C-terminus of the rat and the human BRG1 protein. These two antisera cross-reacted with a protein found in both Xenopus liver and Xenopus oocytes. The Xenopus BRG1-like protein is expressed throughout oogenesis (stages I-VI) and embryogenesis. By injecting an expression vector containing the full-length human BRG1 cDNA into Xenopus oocytes, the relative molecular weight (Mr) of the Xenopus BRG1-like protein was shown to be slightly lower than that of the human BRG1, 190 000 and 200 000, respectively. The Xenopus BRG1-like protein elutes at a Mr of approximately 2 000 000 on Superose HR6trade mark size-exclusion chromatography, indicating that it is part of a larger complex, as are all other known SWI/SNF proteins. Nucleosome remodelling activity was co-eluted with the BRG1 immunogenic activity in both ion-exchange and size-exclusion chromatography.

Chromatin structure of the rat somatotropin gene locus and physical linkage of the rat somatotropin gene and skeletal-muscle sodium-channel gene

Cosmid clones from -32 kb to +74 kb region of the rat somatotropin gene locus were isolated for examination of the chromatin structure in the region from -39 kb to +47 kb by DNase I-sensitivity analysis using rat pituitary-derived GC (somatotropin+, prolactin-), and 235 (somatotropin-, prolactin+) cells, and liver-derived BRL (somatotropin-, prolactin-) cells. DNase I-hypersensitive sites (DHS) specific for somatotropin-producing cells were previously shown to be located exclusively in the -2 kb to +9 kb region [Aizawa, A., Yoneyama, T., Kazahari, K. & Ono, M. (1995) Nucleic Acids Res. 23, 2236-2244]. No other DHS having this specificity was found in the region examined in this study. Except for these and two other DHS located in a cluster in this region, no DHS could be found from -23 kb to +22 kb. DHS having no or less cell-type specificity were scattered about in the -39 kb to -23 kb and +22 kb to +47 kb regions. The polyadenylation site of the human skeletal-muscle Na-channel alpha-subunit gene has been shown present 22 kb upstream from the somatotropin gene [Bennani-Baiti, I. M., Jones, B. K., Liebhaber, S. A. & Cooke, N. E. (1995) Genomics 29, 647-652]. Polyadenylation site of the rat skeletal-muscle Na-channel gene was shown in this study to be at -15.7 kb. The skeletal-muscle Na-channel gene was specifically expressed in skeletal-muscle cells but not in somatotropin-producing cells, and thus the boundary region that ensures the cell-type-specific expression of each gene would appear to be situated between two genes. The region prerequisite for cell-type-specific expression of the rat somatotropin gene was estimated based on the present findings.

The caudal-type homeobox protein Cdx-2 binds to the colon promoter of the carbonic anhydrase 1 gene

Carbonic anhydrase 1 (CA1) is an abundant enzyme in colon epithelia. In the gastrointestinal tract, carbonic anhydrase is vital for NaCl resorption, alkalinization of gut contents, and absorption of short-chain fatty acids. The CA1 gene has two promoters, one of which is specifically active in colon epithelia and the other in erythroid cells. We are investigating the factors that regulate CA1 expression from the colon-specific promoter. Colon-specific deoxyribonuclease I hypersensitive sites (DHS) have been mapped close to the colon transcription initiation site (DHS6c) and in the upstream intron (DHS5c). Using electrophoretic mobility-shift assays to search the 650-bp region which contains DHS6c, we have identified sequences that bind a colon-specific factor (COF1) and by deletion analysis we have narrowed down the COF1-binding motif to a 17-bp sequence. A comparison of this motif with a protein-binding motif in the sucrase-isomaltase gene promoter, competition assays, and antibody studies indicate that COF1 is identical to the homeodomain protein Cdx-2. We propose that Cdx-2 plays an important role in the intestine-specific expression of CA1.

Transcriptional regulatory regions for expression of the rat pyruvate kinase M gene

To study the regulatory mechanism of pyruvate kinase M gene transcription, we analyzed its chromatin structure and cis-acting DNA regions. Two DNase-I-hypersensitive sites were detected in dRLh-84 hepatoma cells, but not in hepatocytes, which coincides with expression of the M gene in the two types of cells. These sites, designated HS2 and HS1, were located around the major transcription start site and about 2.9 kb downstream from this site, respectively. A transient chloramphenicol acetyltransferase expression assay indicated that the region around HS1 did not show any activity, whereas the upstream region up to -457 had promoter activity in hepatoma cells. Most of this activity was lost by a 5'-deletion from -286 to -225. Further analysis identified a cluster of three cis-acting regions from -279 to -216, which are named boxes A, B and C. These regions did not have any independent effect, but the inclusion of all regions were synergistic. These regions were not active in hepatocytes, suggesting that they have cell-type specificity. A gel mobility shift assay indicated that unidentified, but distinct, nuclear proteins bound to the three boxes. These results suggest that transcriptional regulation of the M gene involves alteration of chromatin structure and binding of proteins to three cis-acting elements.

Liver-specific DNase I-hypersensitive sites and DNA methylation pattern in the promoter region of a 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase gene

The mRNA for the liver isozyme of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase is transcribed from the L promoter of gene A. We show here that L-promoter activity is tissue specific. To identify on the gene in situ potential cis-acting sequences, we have examined 15 kb of its 5' region for DNase I-hypersensitive sites detectable on chromatin. We have also evaluated the DNA methylation status of the 3.7-kb encompassing the L promoter. Five DNase I-hypersensitive sites were detected on liver chromatin, three upstream (M1 at position -4500, L2 at position -1000, L1 at position -200) and two downstream (I1 at position +3000, I2 at position +3500) from the L-type mRNA transcription initiation site. Their presence correlated with transcriptional activity as they were not observed on chromatin from kidney, a tissue where gene A is not expressed. Sites M1 and L1 corresponded to the M and L promoters, respectively, providing in vivo evidence for a promoter localization obtained earlier with cloned DNA only. Site I2 coincided with a glucocorticoid-responsive unit described by others, but its presence did not depend on glucocorticoids. Thus, sites L2 and I1 could correspond to novel control elements. While DNA was methylated around position -2000 both in liver and kidney, downstream from that position it was fully demethylated in liver but not in kidney. This pattern changed during development of fetal liver. The data suggest mechanisms for the lack of activity of the L promoter in kidney and for its activation in developing and adult liver.

DNase-I-hypersensitive sites located far upstream of the human c-sis/PDGF-B gene comap with transcriptional enhancers and a silencer and are preceded by (part of) a new transcription unit

The human c-sis gene encodes the B chain of platelet-derived growth factor (PDGF), a potent mitogen for cultured cells of mesenchymal origin. PDGF is stored in the alpha-granules of blood platelets, which are derived from bone marrow megakaryocytes and lack transcriptional machinery. Human myeloid leukemia cell line K562 can be used as a model for megakaryocytes. Phorbol-ester-mediated megakaryocytic differentiation of K562 cells is accompanied by more than 200-fold increase in the c-sis mRNA level. We have now localized transcriptional enhancers at -8.6 kb and -9.9 kb relative to the human c-sis gene transcription start site. The enhancer at -8.6 kb increases activity of the c-sis promoter by 40-60-fold specifically in K562 cells and comaps with a DNase-I-hypersensitivity (DH) site. The enhancer at -9.9 kb increases c-sis promoter activity by 5-10-fold in K562 cells and DH at that site accompanies phorbol-ester-induced megakaryocytic differentiation. In phorbol-ester-treated K562 cells the two enhancers may be negatively influenced by a silencer that comaps with DH at -10.7/-11.0 kb. Reporter gene analysis predicted that combined activity of the upstream enhancers and the c-sis promoter may result in 100-1000-fold higher promoter activity in phorbol-ester-treated K562 cells compared with untreated cells, which can fully explain the more than 200-fold increase in c-sis mRNA level. DH at -8.6 kb and -9.9 kb was also detected in human fibroblasts and in the carcinoma cell lines HeLa and PC3, which express, respectively, undetectable, low and high levels of c-sis mRNA. Although the individual DH sites displayed 4-10-fold enhancer activity in all these cells, they lost most of their biological activity when combined in a larger fragment. In addition we localized (part of) a new transcription unit at approximately 13 kb upstream of the c-sis transcription start site. The corresponding 0.45-kb sis upstream region (sur) transcript is constitutively expressed in all cell lines examined. The expression of the sur transcript is independent of the expression of c-sis mRNA and of the pattern of DH sites far upstream of the c-sis gene. Thus, at present, there is no indication that the upstream DH sites are involved in regulation of expression of the sur gene.

Glucose administration induces the premature expression of liver glucokinase gene in newborn rats. Relation with DNase-I-hypersensitive sites

Glucokinase first appears in the liver of the rat 2 weeks after birth and its activity rapidly increases after weaning on to a high-carbohydrate diet. The appearance of glucokinase is principally due to the increase of plasma insulin and to the decrease of plasma glucagon concentrations. Oral glucose administration to 1- or 10-day-old suckling rats induced an increase in plasma insulin and a fall in plasma glucagon and allowed a rapid accumulation of liver glucokinase mRNA, secondarily to a stimulation of gene transcription. When unrestrained late pregnant rats were infused with glucose during 36 h to induce an increase in fetal plasma insulin and a decrease in fetal plasma glucagon concentrations, glucokinase mRNA was detectable in fetal liver but the level was 100-fold lower than that observed in 1- or 10-day-old suckling rats. It is suggested that the hormonal environment did not allow glucokinase gene expression to be induced in fetal liver and that the absence of expression of glucokinase in suckling rat liver is due to the presence of low plasma insulin and high plasma glucagon levels. The chromatin structure of the glucokinase gene was examined during development by identification of DNase-I-hypersensitive sites from the region comprised between -8 kb upstream and +4 kb downstream of the cap site. Five hypersensitive sites were found: four liver-specific sites upstream of the cap site and one non-specific site in the first intron. These sites are already present in term fetus but the intensity of the two proximal sites located upstream of the cap site increase markedly after birth. This suggests that these sites could be implicated in the regulation of glucokinase gene expression by insulin and glucagon. Full DNase-I-hypersensitivity of these two proximal sites seems necessary for the mature response of glucokinase gene in response to changes in pancreatic hormones concentrations.

High-mobility-group (HMG) proteins and histone H1 subtypes expression in normal and tumor tissues of mouse

Exhaustive extraction of mouse tissues with perchloric acid has been used together with reverse-phase HPLC and electrophoresis to quantify the amounts of chromosomal proteins HMG17, HMG14 and HMGI, relative to histone H1. Normal lung and thymus contain approximately 3% HMG17/HMG14 but only approximately 2% HMGI. In tumor tissues (Lewis lung carcinoma and lymphoma NQ35), the amount of HMG17/HMG14 is not greatly altered but HMGI levels rise considerably, reaching 10% in Lewis lung carcinoma. HMGI synthesis does not replace HMG17/HMG14 proteins, suggesting that HMGI proteins contribute to the structure of chromatin regions in a manner distinct from those of HMG17/HMG14. Ion-spray mass spectrometry has been used to determine the molecular masses of H1 subtypes from the same four mouse tissues. In addition to the six known species H1 zero, H1a, H1b, H1c, H1d and H1e, a newly defined subtype of mass 21,756 Da from Lewis lung carcinoma, named H1L was identified. Several phosphorylated H1 subtypes have also been defined by mass spectrometry. The combined use of reverse-phase HPLC and electrophoresis permitted quantification of these seven histone H1 subtypes in the four mouse tissues. Increased phosphorylation of H1 subtypes in tumors parallels the phosphorylation of HMGI proteins which are present in great amounts, showing that both are involved as post-translational-modified forms in the structure of the chromatin of neoplastic systems.

Localization and functional analysis of DNase-I-hypersensitive sites in the human c-sis/PDGF-B gene transcription unit and its flanking regions

We studied the regulation of the expression of the human c-sis/PDGF-B gene in the following panel of cell lines: K562 cells, in which expression is inducible by phorbol esters; cytotrophoblast-derived cell lines JEG-3 and JAR; carcinoma-derived cell lines PC3, T24 and HeLa, which show extensive differences in c-sis mRNA content; dermal fibroblasts, which do not express the gene. We demonstrate that the wide variety of levels of c-sis mRNA in these cells is mainly determined at the transcription level. Extensive gene rearrangements or amplifications, or significant differences in the stability of the c-sis transcript could not be found. In fibroblasts and placenta cell lines, inaccessibility of the c-sis promoter, rather than the absence of transcription factors that activate it, inhibits expression of the endogenous gene. Examination of the chromatin structure of the transcription unit and immediate flanking regions revealed several cell-type-specific DNase-I-hypersensitivity (DH) sites. Functional analysis of genomic fragments harbouring one or more DH sites showed the presence of negative regulatory elements within intron 1, and of an activating element downstream of the gene. A DH site, located immediately downstream of the promoter in dermal fibroblasts, may regulate accessibility of the promoter by means of specific nucleosome phasing.

Transiently and stably introduced CCAAT/enhancer-binding-protein genes are constitutively expressed in cultured cells

CCAAT/enhancer-binding protein (C/EBP) is expressed in certain cell types including hepatocytes and adipocytes. In order to understand the mechanisms that control the expression of the mouse C/EBP gene in the liver as well as in adipocytes, we have studied both the endogenous gene and transfected C/EBP gene constructs. The initiation site of transcription was identified and a strong liver-specific DNase-I hypersensitive site located at -3 kb, which does not appear to contribute functionally to the regulation of the gene in a variety of either transiently or stably transfected cells with constructs which include sequences up to 6-kb upstream of the transcription start. C/EBP gene expression during the transition from preadipocytes to adipocytes was shown to be controlled at the level of transcription. However, adipocytes stably transfected with constructs that include -3.3 kb upstream of the C/EBP gene do not express the reporter genes in a differentiation-specific manner. We detected several DNA-binding proteins that interact with the upstream sites of the C/EBP gene. Those include two labile and two heat-stable site-specific DNA-binding proteins that are present in nuclear extracts from several tissues and cultured cell lines.

Histone hyperacetylation is accompanied by changes in DNA topology in vivo

The effect of histone acetylation on the topology of plasmids transfected into COS7 cells was examined. Parallel determinations of histone profiles and DNA topology showed that with increasing levels of acetylation the minichromosomal DNA is gradually relaxed. This effect could not be attributed to the increased transcriptional activity accompanying butyrate treatment since plasmids with different promoter strengths exhibited similar superhelical densities. Considering that the number of nucleosomes/minichromosome were constant under these conditions, the data suggest that in vivo histone hyperacetylation reduces the linking number change/nucleosome.

The repair of double-strand breaks and S1 nuclease-sensitive sites can be monitored chromosome-specifically in Saccharomyces cerevisiae using pulse-field gel electrophoresis

Repair under non-growth conditions of DNA double-stranded breaks (DSBs) and S1 nuclease-sensitive sites (SSSs; e.g. DNA damage which is processed by in vitro treatment with S1 nuclease to DSBs) induced by [60Co]-gamma-rays (200 Gy; anoxic conditions) was monitored in a diploid repair-competent strain of Saccharomyces cerevisiae. We used pulsed-field gel electrophoresis (PFGE), which allows the separation of chromosome-sized yeast DNA molecules, to determine the number of DSBs and SSSs in individual chromosome species of yeast. Our results indicate that SSSs which have been regarded as clusters of base damage in opposite DNA strands are repaired efficiently in a repair-proficient diploid strain of yeast. The time course of SSS repair is comparable to the one of DSB repair, indicating similarities in the molecular mechanism. Both types of repair kinetics are different for different chromosome species.

Structural characterization of the human DNA topoisomerase I gene promoter

We have isolated a genomic DNA fragment from HeLa cells containing the promoter region and the first two exons of the human gene encoding DNA topoisomerase I (hTOP1). Transcription of hTOP1 mRNA initiates at multiple sites which are clustered 247 nucleotides and 210 nucleotides upstream of the translation-initiation site of the protein coding region. The nucleotide sequence of the region preceding the transcription-initiation sites is G/C rich and contains sequence motifs which are known binding sites of the transcription factors Oct1 (octameric transcription factor 1), Sp1 and AP2 (activator protein 2). Furthermore, one cAMP-responsive element is present 50 nucleotides upstream of the transcription-initiation site nearest the 5' end. Neither TATA nor CAAT boxes were found in the promoter region of the hTOP1 gene. A 918-bp fragment containing the sequence elements described above drives the transient expression of a chloramphenicol acetyl transferase (CAT) gene sequence in transfected HeLa and 293 cells. In addition we analyzed a 10-kb fragment containing the promoter and exons 1 and 2 for regions of DNase I hypersensitivity. We detected one prominent DNase-I-hypersensitive region in the promoter close to the putative transcription-factor-binding sites and several weaker regions in intron 2.

Chromosome-specific identification and quantification of S1 nuclease-sensitive sites in yeast chromatin by pulsed-field gel electrophoresis

Sites that are sensitive to the single-strand-specific endonuclease S1 ('S1-sensitive sites', SSS) occur in native chromatin and, like DNA double-stranded breaks (DSB), they are induced by DNA-damaging agents, such as ionizing radiation. We have developed a method to quantify SSS and DSB in yeast chromatin by using pulsed-field gel electrophoresis (PFGE) to separate the intact chromosomal-length DNA molecules from the lower molecular-weight broken ones. Direct evaluation of the photonegatives of the ethidium bromide-stained gels by laser densitometry enabled us to calculate the numbers of DSB and SSS per DNA molecule. These numbers were determined from the bulk of the non-separated genomic DNA of yeast, corresponding to a single band in the PFGE (pulse time 10 seconds), and in each of the eight largest yeast chromosomes, corresponding to distinct bands in the PFGE gels (pulse time 50 seconds), which were not superimposed by the smear of the broken, low molecular-weight DNA. Furthermore, the induction of DSB and SSS in a specific chromosome (circular chromosome III) was determined by Southern hybridization of the PFGE gels with a suitable centromere probe, followed by densitometry of the autoradiographs. Our method allows the chromosome-specific monitoring of DSB and all those DNA structures that are processed either in vivo or in vitro into DSB and which may not be distributed randomly within the genome.

The human lysozyme gene. Sequence organization and chromosomal localization

We have isolated two overlapping recombinant lambda-phage clones from a genomic lambda-EMBL3 library containing 25 kb of the human lysozyme gene region. Furthermore a full-lenght human lysozyme cDNA clone of 1.5 kb was isolated from a human placenta cDNA library. Nucleotide sequences of the entire structural gene and the cDNA clone were determined. The human lysozyme gene spans 5856 bp and its sequence organization with four exons and three introns is homologous to the chicken lysozyme gene and the human alpha-lactalbumin gene. Human and chicken lysozyme genes differ mainly in the size of their introns and 3' non-coding region. Four Alu repetitive elements were found in the human lysozyme gene, one in each intron and one on the fourth exon. Lysozyme transcripts of 1.6 kb and 0.6 kb in size were detected in human myeloid cell lines U-937, HL-60 and THP-1 and surprisingly in human hepatoma cell lines HepG2 and Hep3B. The lysozyme gene locus was assigned to human chromosome 12 by hybridization to a panel of DNAs from human-rodent somatic cell hybrids.