Evolution of chromosome bands: molecular ecology of noncoding DNA

The complete nucleotide sequence of the human immunoglobulin heavy chain variable region locus

The complete nucleotide sequence of the 957-kb DNA of the human immunoglobulin heavy chain variable (VH) region locus was determined and 43 novel VH segments were identified. The region contains 123 VH segments classifiable into seven different families, of which 79 are pseudogenes. Of the 44 VH segments with an open reading frame, 39 are expressed as heavy chain proteins and 1 as mRNA, while the remaining 4 are not found in immunoglobulin cDNAs. Combinatorial diversity of VH region was calculated to be approximately 6,000. Conservation of the promoter and recombination signal sequences was observed to be higher in functional VH segments than in pseudogenes. Phylogenetic analysis of 114 VH segments clearly showed clustering of the VH segments of each family. However, an independent branch in the tree contained a single VH, V4-44.1P, sharing similar levels of homology to human VH families and to those of other vertebrates. Comparison between different copies of homologous units that appear repeatedly across the locus clearly demonstrates that dynamic DNA reorganization of the locus took place at least eight times between 133 and 10 million years ago. One nonimmunoglobulin gene of unknown function was identified in the intergenic region.

Initiation of DNA replication at CpG islands in mammalian chromosomes

CpG islands are G+C-rich regions approximately 1 kb long that are free of methylation and contain the promoters of many mammalian genes. Analysis of in vivo replication intermediates at three hamster genes and one human gene showed that the CpG island regions, but not their flanks, were present in very short nascent strands, suggesting that they are replication origins (ORIs). CpG island-like fragments were enriched in a population of short nascent strands from human erythroleukaemic cells, suggesting that islands constitute a significant fraction of endogenous ORIs. Correspondingly, bulk CpG islands were found to replicate coordinately early in S phase. Our results imply that CpG islands are initiation sites for both transcription and DNA replication, and may represent genomic footprints of replication initiation.

Chromosomal response of insect and mammalian cells to streptonigrin: a comparative study

We assessed the chromosomal response of insect (mosquito, Aedes albopictus) and mammalian (Chinese hamster ovary, CHO) cells to streptonigrin (SN). Both types of cells were pulse-treated for 20 min with increasing doses of SN and the frequency of chromosome aberrations and sister chromatid exchanges (SCEs) for each SN dose was determined. Our results show that the SN doses inducing remarkable chromosome damage (expressed as frequency of aberrations per cell and per chromosome) in CHO cells fail to produce a significant increase of aberrations in mosquito chromosomes. Moreover, CHO cells exhibited a dose-dependent increase in SCEs which was not observed in mosquito cells. Our results show that while mammalian cells are very sensitive, insect cells are very resistant to SN at the chromosome level. It is possible that variations in the chromatin fibril structure and in the intracellular antioxidant pool may be responsible for the differential response of insect and mammalian chromosomes to SN.

Cytogenetic study of the genus Saguinus (Callithrichidae, Primates)

Eight subspecies from the genus Saguinus (S. fuscicollis fuscicollis, S. fuscicollis weddelli, S. bicolor bicolor, S. bicolor martinsi, S. mystax mystax, S. imperator imperator, S. midas midas, and S. midas niger) were studied. Five of them (S. f. fuscicollis, S. f. weddelli, S. b. martinsi, S. m. mystax and S. i. imperator) had their karyotypes described for the first time. Conventional coloration, banding patterns G, C and NOR, and G/C sequential banding tecniques were used. All samples showed the same diploid number (2n = 46). The patterns of the G, C and NOR bands were very similar with little differences in the quantity and constitutive heterochromatin distribution of the autosomes. Constitutive heterochromatin was observed only in telomeric regions of some chromosomes of S. f. fuscicollis and S. f. weddelli. The X chromosome was the same in all subspecies, but chromosome Y differed in size and morphology. XX/XY chimerism was verified in all subspecies

High-resolution analysis of DNA replication domain organization across an R/G-band boundary

Establishing how mammalian chromosome replication is regulated and how groups of replication origins are organized into replication bands will significantly increase our understanding of chromosome organization. Replication time bands in mammalian chromosomes show overall congruency with structural R- and G-banding patterns as revealed by different chromosome banding techniques. Thus, chromosome bands reflect variations in the longitudinal structure and function of the chromosome, but little is known about the structural basis of the metaphase chromosome banding pattern. At the microscopic level, both structural R and G bands and replication bands occupy discrete domains along chromosomes, suggesting separation by distinct boundaries. The purpose of this study was to determine replication timing differences encompassing a boundary between differentially replicating chromosomal bands. Using competitive PCR on replicated DNA from flow-sorted cell cycle fractions, we have analyzed the replication timing of markers spanning roughly 5 Mb of human chromosome 13q14.3/q21.1. This is only the second report of high-resolution analysis of replication timing differences across an R/G-band boundary. In contrast to previous work, however, we find that band boundaries are defined by a gradient in replication timing rather than by a sharp boundary separating R and G bands into functionally distinct chromatin compartments. These findings indicate that topographical band boundaries are not defined by specific sequences or structures.

Precise switching of DNA replication timing in the GC content transition area in the human major histocompatibility complex

The human genome is composed of long-range G+C% (GC%) mosaic structures thought to be related to chromosome bands. We previously reported a boundary of megabase-sized GC% mosaic domains at the junction area between major histocompatibility complex (MHC) classes II and III, proposing it as a possible chromosome band boundary. DNA replication timing during the S phase is known to be correlated cytogenetically with chromosome band zones, and thus the band boundaries have been predicted to contain a switch point for DNA replication timing. In this study, to identify to the nucleotide sequence level the replication switch point during the S phase, we determined the precise DNA replication timing for MHC classes II and III, focusing on the junction area. To do this, we used PCR-based quantitation of nascent DNA obtained from synchronized human myeloid leukemia HL60 cells. The replication timing changed precisely in the boundary region with a 2-h difference between the two sides, supporting the prediction that this region may be a chromosome band boundary. We supposed that replication fork movement terminates (pauses) or significantly slows in the switch region, which contains dense Alu clusters; polypurine/polypyrimidine tracts; di-, tri-, or tetranucleotide repeats; and medium-reiteration-frequency sequences. Because the nascent DNA in the switch region was recovered at low efficiency, we investigated whether this region is associated with the nuclear scaffold and found three scaffold-associated regions in and around the switch region.

The repair of UV-induced cyclobutane pyrimidine dimers in the individual genes Gart, Notch and white from isolated brain tissue of Drosophila melanogaster

We have measured the induction and removal of UV-induced cyclobutane pyrimidine dimers from defined, DNA sequences in brains isolated from wild-type Drosophila melanogaster third instar larvae. Brains were exposed to a single dose of 500 J/m2 UVB and kept in the dark for up to 48 h. Within 48 h after irradiation, 50% of the dimers are removed from the actively transcribed genes Gart and Notch. Moreover, these kinetics are similar to the time course of dimer removal measured in the transcriptionally inactive white gene. It is further demonstrated that the genome overall is repaired at a similar rate. The results are discussed with respect to the in vivo irradiation of brains and to the data found for gene-specific repair in other eukaryotes.

Methylation of genomes and genes at the invertebrate-vertebrate boundary

Patterns of DNA methylation in animal genomes are known to vary from an apparent absence of modified bases, via methylation of a minor fraction of the genome, to genome-wide methylation. Representative genomes from 10 invertebrate phyla comprise predominantly nonmethylated DNA and (usually but not always) a minor fraction of methylated DNA. In contrast, all 27 vertebrate genomes that have been examined display genome-wide methylation. Our studies of chordate genomes suggest that the transition from fractional to global methylation occurred close to the origin of vertebrates, as amphioxus has a typically invertebrate methylation pattern whereas primitive vertebrates (hagfish and lamprey) have patterns that are typical of vertebrates. Surprisingly, methylation of genes preceded this transition, as many invertebrate genes have turned out to be heavily methylated. Methylation does not preferentially affect genes whose expression is highly regulated, as several housekeeping genes are found in the heavily methylated fraction whereas several genes expressed in a tissue-specific manner are in the nonmethylated fraction.

A relationship between GC content and coding-sequence length

Since base composition of translational stop codons (TAG, TAA, and TGA) is biased toward a low G+C content, a differential density for these termination signals is expected in random DNA sequences of different base compositions. The expected length of reading frames (DNA segments of sense codons flanked by in-phase stop codons) in random sequences is thus a function of GC content. The analysis of DNA sequences from several genome databases stratified according to GC content reveals that the longest coding sequences-exons in vertebrates and genes in prokaryotes-are GC-rich, while the shortest ones are GC-poor. Exon lengthening in GC-rich vertebrate regions does not result, however, in longer vertebrate proteins, perhaps because of the lower number of exons in the genes located in these regions. The effects on coding-sequence lengths constitute a new evolutionary meaning for compositional variations in DNA GC content.

The role of constrained self-organization in genome structural evolution

A hypothesis of genome structural evolution is explored. Rapid and cohesive alterations in genome organization are viewed as resulting from the dynamic and constrained interactions of chromosomal subsystem components. A combination of macromolecular boundary conditions and DNA element involvement in far-from-equilibrium reactions is proposed to increase the complexity of genomic subsystems via the channelling of genome turnover; interactions between subsystems create higher-order subsystems expanding the phase space for further genetic evolution. The operation of generic constraints on structuration in genome evolution is suggested by i) universal, homoplasic features of chromosome organization and ii) the metastable nature of genome structures where lower-level flux is constrained by higher-order structures. Phenomena such as 'genomic shock', bursts of transposable element activity, concerted evolution, etc., are hypothesized to result from constrained systemic responses to endogenous/exogenous, micro/macro perturbations. The constraints operating on genome turnover are expected to increase with chromosomal structural complexity, the number of interacting subsystems, and the degree to which interactions between genomic components are tightly ordered.

The chicken beta 2-microglobulin gene is located on a non-major histocompatibility complex microchromosome: a small, G+C-rich gene with X and Y boxes in the promoter

beta 2-Microglobulin is an essential subunit of major histocompatibility complex (Mhc) class I molecules, which present antigenic peptides to T lymphocytes. We sequenced a number of cDNAs and two genomic clones corresponding to chicken beta 2-microglobulin. The chicken beta 2-microglobulin gene has a similar genomic organization but smaller introns and higher G+C content than mammalian beta 2-microglobulin genes. The promoter region is particularly G+C-rich and contains, in addition to interferon regulatory elements, potential S/W, X, and Y boxes that were originally described for mammalian class II but not class I alpha or beta 2-microglobulin genes. There is a single chicken beta 2-microglobulin gene that has little polymorphism in the coding region. Restriction fragment length polymorphisms from Mhc homozygous lines, Mhc congenic lines, and backcross families, as well as in situ hybridization, show that the beta 2-microglobulin gene is located on a microchromosome different from the one that contains the chicken Mhc. We propose that the structural similarities between the beta 2-microglobulin and Mhc genes in the chicken are due to their presence on microchromosomes and suggest that these features and the microchromosomes appeared by deletion of DNA in the lineage leading to the birds.

Chicken MHC molecules, disease resistance and the evolutionary origin of birds

Birds, like mammals, have highly a polymorphic MHC that determines strong allograft rejection. However, chickens have a much smaller, more compact and simpler MHC than mammals, as though the MHC has been stripped down to the essentials during evolution. The selection pressure on a single MHC gene should be much stronger than on a large multigene family, and, in contrast to mammals, there are a number of viral diseases for which resistance and susceptibility are determined by particular chicken MHC haplotypes. We have determined the peptide motifs for the dominant class I molecules from a number of chicken MHC haplotypes, which may explain some disease associations quite simply. Other disease associations, like the famous examples with Marek's disease, may be due to polymorphism in the level of expression of MHC class I molecules. We believe that the compact and simple nature of the MHC is due to the presence of microchromosomes in birds and suggest that the evolutionary origin of birds has been strongly influenced by the emergence of microchromosomes.

G-banding and chromosome condensation in the ant, Tapinoma nigerrimum

Well-defined G-bands were obtained on metaphase chromosomes from Tapinoma nigerrimum using trypsin and warm 2 x SSC in sequence. The G-banded pattern allowed the identification of all chromosomes. Evidence for asynchronous condensation of the chromosomes of this species is provided. Different banding patterns were obtained when metaphase chromosomes were stained with DA/DAPI alone and with DA/DAPI after a standard G-banding procedure. The G-banding phenomenon is discussed using the result obtained.

The hyperactive X chromosome is not early replicating in mitotically active somatic cells of Drosophila nasuta males

The temporal order of replication of the X chromosome(s) in mitotically dividing male and female cells in early embryos and in brain ganglia of Drosophila nasuta larvae was examined using [3H]thymidine pulse labelling and autoradiography. Both the X chromosomes in female cells and the single X chromosome in male cells replicated in complete synchrony with the autosome set in the nucleus. Thus, unlike the well-known early completion of replication by the hemizygous X chromosome in polytene nuclei in the salivary glands of male Drosophila larvae, the single X chromosome in mitotically dividing cells does not replicate earlier than the autosomes. We conclude that transcriptional hyperactivity of the single X chromosome required for dosage compensation in somatic cells of male Drosophila is not dependent upon its early replication.

High yield of restriction fragment length polymorphisms in two-dimensional separations of human genomic DNA

We have investigated the extent to which restriction fragment length polymorphism can be detected by two-dimensional electrophoresis of end-labeled genomic restriction fragments. Genomic DNA was digested with NotI and EcoRV and labeled at the NotI recognition site before first-dimension electrophoresis in disk gels. DNA in the disk gels was further digested in situ with HinfI prior to second-dimension electrophoresis, yielding patterns in which approximately 2000 end-labeled fragments were simultaneously visualized. On the basis of studies of 6 mother/father/child trios, a group of 184 fragments was organized into 85 polymorphic systems in which all allelic fragments were detectable in the 2-D patterns. Another 206 fragments varied as to their presence among individuals, but their relatedness to other fragments was not established. Our data indicate that a large number of DNA polymorphisms can be simultaneously scored in 2-D separations of genomic DNA fragments.

A boundary of long-range G + C% mosaic domains in the human MHC locus: pseudoautosomal boundary-like sequence exists near the boundary

The human genome is composed of long-range G+C% (GC%) mosaic structures related to chromosome bands. We found the human MHC locus to be an example of megabase-level GC% mosaic structures and predicted a possible boundary of the megabase-level domains within an undercharacterized 450-kb region harboring the junction of MHC classes II and III. Chromosome walking of the 450-kb region and base-compositional analysis precisely located the boundary of the mosaic domains, disclosing a sharp GC% transition. Near the transition point there was a 20-kb dense Alu cluster, a 30-kb dense LINE-1 cluster, and a sequence highly homologous with the pseudoautosomal boundary of the short arms of human sex chromosomes (PAB1X and PAB1Y); PAB1X and PAB1Y are the interface between sex-specific and pseudoautosomal regions. Many PAB1XY-like sequences (PABLs) were detected by hybridization against genomic DNA, and the new sequences defined the complete form of PABLs to be about 650 nt.

The distribution of CpG islands in mammalian chromosomes

Using fluorescent in situ suppression hybridization to metaphase chromosomes, we have directly shown that CpG islands are predominantly found in the early replicating (R band) regions of the genome. Conversely, late replicating (G band) DNA is sparsely populated with islands. The very highest concentration of CpG islands is in a subset of R bands, most of which are known as T bands. We suggest that there is an interdependence between the differences in island density and the behaviour of chromosomal domains. Our findings indicate which regions of the genome will yield the highest density of coding sequence information. An awareness of local island density may influence the choice of method for identifying exons in genomic DNA.

Comparative chromosome painting discloses homologous segments in distantly related mammals

Comparative chromosome painting, termed ZOO-FISH, using DNA libraries from flow sorted human chromosomes 1, 16, 17 and X, and mouse chromosome 11 discloses the presence of syntenic groups in distantly related mammalian orders ranging from primates (Homo sapiens), rodents (Mus musculus), even-toed ungulates (Muntiacus muntjak vaginalis and Muntiacus reevesi) and whales (Balaenoptera physalus). These mammalian orders have evolved separately for 55-80 million years (Myr). We conclude that ZOO-FISH can be used to generate comparative chromosome maps of a large number of mammalian species.

Number of CpG islands and genes in human and mouse

Estimation of gene number in mammals is difficult due to the high proportion of noncoding DNA within the nucleus. In this study, we provide a direct measurement of the number of genes in human and mouse. We have taken advantage of the fact that many mammalian genes are associated with CpG islands whose distinctive properties allow their physical separation from bulk DNA. Our results suggest that there are approximately 45,000 CpG islands per haploid genome in humans and 37,000 in the mouse. Sequence comparison confirms that about 20% of the human CpG islands are absent from the homologous mouse genes. Analysis of a selection of genes suggests that both human and mouse are losing CpG islands over evolutionary time due to de novo methylation in the germ line followed by CpG loss through mutation. This process appears to be more rapid in rodents. Combining the number of CpG islands with the proportion of island-associated genes, we estimate that the total number of genes per haploid genome is approximately 80,000 in both organisms.

In human chromosomes telomeric regions are enriched in CpGs relative to R-bands

Human chromosomes were in situ nick-translated using as nicking agents the endonucleases MspI (CCGG), its methyl-sensitive isoschizomer HpaII, HaeIII (GGCC), SacII (CCGCGG), EcoRI (GAATTC) and DNaseI. We show that in metaphase chromosomes R-bands are enriched, as compared with G-bands, in the dinucleotide CpG but no more than what is expected on the basis of their relative G+C content. The telomeric regions, on the contrary, besides having a chromatin conformation that is particularly relaxed and accessible to endonucleases, also show an enrichment in CpGs.

The genomic synteny at DNA level between human and chimpanzee chromosomes

The evolutionary relationship between human (Homo sapiens) and chimpanzee (Pan troglodytes) has been the subject of debate and scrutiny for over two decades. The close relationship established by numerous parameters may or may not reflect homology at the DNA level. The recent advent of a molecular method termed the chromosome in situ suppression hybridization (CISS)-technique has prompted us to explore the phylogenetic relationship at the DNA sequence level. Cross-hybridization data using human-derived whole chromosome paints (WCPs) suggests an apparent genomic synteny with chimpanzee chromosomes at the DNA level, thus providing a better understanding of an evolutionary relationship between humans and chimpanzees.

Chromosome bands--flavours to savour

The mammalian chromosome is longitudinally heterogeneous in structure and function and this is the basis for the specific banding patterns produced by various chromosome staining techniques. The two most frequently used techniques are G, or Giemsa banding and R, or reverse banding. Each type of stained band is characterised by variations in gene density, time of replication, base composition, density of repeat sequences, and chromatin packaging. It is increasingly apparent that R and G bands, which are complementary to each other, represent separate compartments of the euchromatic human genome, with R bands containing the vast majority of genes. R bands are also more GC-rich, contain a higher density of Alu repeats, and replicate earlier in S phase, than G bands. These properties may be interdependent and may have coevolved.

Non-uniform distribution of methylatable CCGG sequences on human chromosomes as shown by in situ methylation

We carried out in situ methylation of human chromosomes with the HpaII methylase using [3H]methyl-S-adenosyl-L-methionine as the methyl group carrier. Autoradiographs localising [3H]methyl groups show methylatable CCGG sequences in the R-bands as well as in the short arms of the acrocentric chromosomes that include ribosomal DNA. The strongest labelling was observed over a subset of R-bands, including T-bands. Since methylatable CCGG sequences are representative of the unmethylated fraction of DNA, we suggest that differences in the degree of DNA methylation could be involved in the structure and function of chromosomal bands.

Temporal order of DNA replication in the H-2 major histocompatibility complex of the mouse

As an approach to mapping replicons in an extended chromosomal region, the temporal order of DNA replication was analyzed in the murine major histocompatibility gene complex (MHC). Replicating DNA from T-lymphoma and myelomonocyte cell lines was density labeled with bromodeoxyuridine and extracted from cells which had been fractionated into different stages of S phase by centrifugal elutriation. The replicating DNA from each fraction of S phase was separated from nonreplicating DNA on density gradients, blotted, and hybridized with 34 specific MHC probes. The earliest replication occurred in the vicinity of transcribed genes K, HAM1 and HAM2, RD, B144, D, L, T18, and T3. The temporal order of replication of groups of DNA segments suggests the location of five or six replicons within the H-2 complex, some of which appear to be either unidirectional or markedly asymmetric. The rates of replication through each of these apparent replicons appear to be similar. The TL region of the S49.1 T-lymphoma cells, which contains at least three transcribed genes, replicates earlier than the inactive TL region of WEHI-3 myelomonocytic cells. These results provide further evidence of a relationship between transcription and the initiation of DNA replication in mammalian cells. The mouse MHC examined in this study is the largest chromosomal region (> 2,000 kb) measured for timing of replication to date.

Temporal order of DNA replication in the H-2 major histocompatibility complex of the mouse

As an approach to mapping replicons in an extended chromosomal region, the temporal order of DNA replication was analyzed in the murine major histocompatibility gene complex (MHC). Replicating DNA from T-lymphoma and myelomonocyte cell lines was density labeled with bromodeoxyuridine and extracted from cells which had been fractionated into different stages of S phase by centrifugal elutriation. The replicating DNA from each fraction of S phase was separated from nonreplicating DNA on density gradients, blotted, and hybridized with 34 specific MHC probes. The earliest replication occurred in the vicinity of transcribed genes K, HAM1 and HAM2, RD, B144, D, L, T18, and T3. The temporal order of replication of groups of DNA segments suggests the location of five or six replicons within the H-2 complex, some of which appear to be either unidirectional or markedly asymmetric. The rates of replication through each of these apparent replicons appear to be similar. The TL region of the S49.1 T-lymphoma cells, which contains at least three transcribed genes, replicates earlier than the inactive TL region of WEHI-3 myelomonocytic cells. These results provide further evidence of a relationship between transcription and the initiation of DNA replication in mammalian cells. The mouse MHC examined in this study is the largest chromosomal region (> 2,000 kb) measured for timing of replication to date.

Absence of strand-specific repair of cyclobutane pyrimidine dimers in active genes in Drosophila melanogaster Kc cells

Strand-specific excision repair of UV-induced cyclobutane pyrimidine dimers was investigated in three genes: Gart, Notch and white in the permanent Kc cell line derived from wild-type Drosophila melanogaster embryonic cells. In this cell line Gart and Notch are transcriptionally active, whereas white is not expressed. Cells were irradiated with 10 or 15 J/m2 ultraviolet (UV) light (predominantly 254 nm). In all three genes, cyclobutane pyrimidine dimers were removed from the non-transcribed strand at the same rate and to the same extent as from the transcribed strand, indicating the absence of strand-specific repair in permanent Drosophila embryonic cell lines.

The role of DNA replication and isochores in generating mutation and silent substitution rate variance in mammals

It has been suggested that isochores are maintained by mutation biases, and that this leads to variation in the rate of mutation across the genome. A model of DNA replication is presented in which the probabilities of misincorporation and proofreading are affected by the composition and concentration of the free nucleotide pools. The relationship between sequence G+C content and the mutation rate is investigated. It is found that there is very little variation in the mutation rate between sequences of different G+C contents if the total concentration of the free nucleotides remains constant. However, variation in the mutation rate can be arbitrarily large if some mismatches are proofread and the total concentration of free nucleotides varies. Hence the model suggests that the maintenance of isochores by the replication of DNA in free nucleotide pools of biased composition does not lead per se to mutation rate variance. However, it is possible that changes in composition could be accompanied by changes in concentration, thus generating mutation rate variance. Furthermore, there is the possibility that germ-line selection could lead to alterations in the overall free nucleotide concentration through the cell cycle. These findings are discussed with reference to the variance in mammalian silent substitution rates.

Evolutionary consequences of nonrandom damage and repair of chromatin domains

Some evolutionary consequences of different rates and trends in DNA damage and repair are explained. Different types of DNA damaging agents cause nonrandom lesions along the DNA. The type of DNA sequence motifs to be preferentially attacked depends upon the chemical or physical nature of the assaulting agent and the DNA base composition. Higher-order chromatin structure, the nonrandom nucleosome positioning along the DNA, the absence of nucleosomes from the promoter regions of active genes, curved DNA, the presence of sequence-specific binding proteins, and the torsional strain on the DNA induced by an increased transcriptional activity all are expected to affect rates of damage of individual genes. Furthermore, potential Z-DNA, H-DNA, slippage, and cruciform structures in the regulatory region of some genes or in other genomic loci induced by torsional strain on the DNA are more prone to modification by genotoxic agents. A specific actively transcribed gene may be preferentially damaged over nontranscribed genes only in specific cell types that maintain this gene in active chromatin fractions because of (1) its decondensed chromatin structure, (2) torsional strain in its DNA, (3) absence of nucleosomes from its regulatory region, and (4) altered nucleosome structure in its coding sequence due to the presence of modified histones and HMG proteins. The situation in this regard of germ cell lineages is, of course, the only one to intervene in evolution. Most lesions in DNA such as those caused by UV or DNA alkylating agents tend to diminish the GC content of genomes. Thus, DNA sequences not bound by selective constraints, such as pseudogenes, will show an increase in their AT content during evolution as evidenced by experimental observations. On the other hand, transcriptionally active parts may be repaired at rates higher than inactive parts of the genome, and proliferating cells may display higher repair activities than quiescent cells. This might arise from a tight coupling of the repair process with both transcription and replication, all these processes taking place on the nuclear matrix. Repair activities differ greatly among species, and there is a good correlation between life span and repair among mammals. It is predicted that genes that are transcriptionally active in germ-cell lineages have a lower mutation rate than bulk DNA, a circumstance that is expected to be reflected in evolution. Exception to this rule might be genes containing potential Z-DNA, H-DNA, or cruciform structures in their coding or regulatory regions that appear to be refractory to repair.(ABSTRACT TRUNCATED AT 400 WORDS)

Induction of G- and R-banding in human chromosomes by the demethylating agent S-adenosyl-L-homocysteine

In this report we describe the procedure of growing human lymphocytes with the demethylating agent S-adenosyl-L-homocysteine (SAH). After this treatment, which is not toxic for cell survival, both R- and G-banding were obtained by new experimental procedures: R-bands have been directly demonstrated with the GC-specific fluorochrome chromomycin A3 without the necessity of any AT-specific counterstaining agent; simultaneous G-banding and active nucleolar organizer regions have been obtained by silver impregnation of chromosomes and subsequent Giemsa staining. These results suggest a possible relationship between local differences in DNA methylation and the determination of the banded chromosome structure.

Differential binding of human nuclear proteins to Alu subfamilies

Several diagnostic differences that distinguish human Alu subfamilies are clustered just downstream from the B box of the RNA polymerase III promoter; we tentatively refer to this diagnostic region as the DB box. Assuming that this region might determine the relative transcriptional activity of Alu subfamilies, we examined the interaction of nuclear proteins with DB box sequences representing different Alu subfamilies. Gel mobility shift assays suggest the existence of two factors which discriminate among the DB boxes of different Alu subfamilies: 1) An abundant, ca. 50 kd, protein binds more stably to a young 'PV' Alu subfamily (PVS) than to the older major subfamily (MS). 2) Methylation of CpG dinucleotides stimulates the binding of a less abundant, ca. 70 kd, protein to the DB boxes of younger Alu subfamilies.

In vivo gene amplification in non-cancerous cells: cholinesterase genes and oncogenes amplify in thrombocytopenia associated with lupus erythematosus

The ACHE and BCHE genes, encoding the acetylcholine hydrolysing enzymes acetylcholinesterase (ACHE) and butyrylcholinesterase (BCHE), co-amplify with several oncogenes in leukemic patients with platelet deficiency (thrombocytopenia). This and other experiments implicated ACHE and BCHE in the development of bone marrow megakaryocytes, the progenitors of platelets. Therefore, we wished to find out whether cholinesterase gene amplification would also occur in non-cancerous platelet disorders and, if so, whether oncogenes would amplify in such cases as well. The autoimmune disease systemic lupus erythematosus (SLE) presents an appropriate model system for this issue, since patients with SLE may suffer from thrombocytopenia resistant to most treatment modalities. Here, we report a 40-80-fold amplification of genomic sequences from the ACHE and BCHE genes as well as the C-raf, V-sis and C-fes/fps oncogenes in peripheral blood cells from an SLE patient with severe thrombocytopenia. PvuII restriction analysis and DNA blot hybridization of the amplified ACHE and BCHE sequences demonstrated apparent aberrations in both genes, suggesting that malfunctioning of modified, partially amplified cholinesterase genes may be involved in the etiology of thrombocytopenia associated with SLE. These observations imply that cholinergic mechanisms regulate megakaryocytopoiesis, shed new light on the diverse hematologic findings characteristic of SLE, and may become valuable as diagnostic, treatment and prognostic tools in the follow-up of patients suffering from thrombocytopenia associated with SLE. Furthermore, these findings reinforce the notion that cholinesterase gene amplifications are causally related with platelet abnormalities in multiple hemopoietic disorders.

Evidence that both G + C rich and G + C poor isochores are replicated early and late in the cell cycle

Since the G + C content of a gene is correlated to that of the isochore in which it resides, and early replicating isochores are thought to be relatively G + C rich, early replicating genes should also be rich in G + C. This hypothesis is tested on a sample of 44 mammalian genes for which replication time data and sequence information are available. Early replicating genes do not appear to be more G + C rich than late replicating genes, instead there is considerable variation in the G + C content of genes replicated during both halves of S phase. These results show that both G + C rich and poor fractions of the genome are replicated early and late in the cell cycle, and suggest that isochores are not maintained by the replication of DNA sequences in compositionally biased free nucleotide pools.

Revisiting junk DNA

The distribution of functions within genomes of higher organisms relative to processes that lead to the spread of mutations in populations is examined in its general outlines. A number of points are enumerated that collectively put in question the concept of junk DNA: the plausible compatibility of DNA function with rapid substitution rates; the likelihood of superimposed functions along much of eukaryotic DNA; the potential for a merely conditional functionality in sequence repeats; the apparent adoption of macromolecular waste as a strategy for maintaining a function without selective grooming of individual sequence repeats that carry out the function; the likely requirement that any DNA sequence must be "polite" vis-'a-vis (compatible with) functional sequences in its genomic environment; the existence in germ-cell lineages of selective constraints that are not apparent in populations of individuals; and the fact that DNA techtonics - the appearance and disappearance of genomic DNA - are not incompatible with function. It is pointed out that the inverse correlation between functional constraints and rates of substitution cannot be claimed to be pillar of the neutral theory, because it is also predicted from a selectionist viewpoint. The dispensability of functional structures is brought into relation with the concept of reproductive sufficiency the survivability of genotypes in the absence of fitter alleles.

Recent evidence for evolution of the genetic code

The genetic code, formerly thought to be frozen, is now known to be in a state of evolution. This was first shown in 1979 by Barrell et al. (G. Barrell, A. T. Bankier, and J. Drouin, Nature [London] 282:189-194, 1979), who found that the universal codons AUA (isoleucine) and UGA (stop) coded for methionine and tryptophan, respectively, in human mitochondria. Subsequent studies have shown that UGA codes for tryptophan in Mycoplasma spp. and in all nonplant mitochondria that have been examined. Universal stop codons UAA and UAG code for glutamine in ciliated protozoa (except Euplotes octacarinatus) and in a green alga, Acetabularia. E. octacarinatus uses UAA for stop and UGA for cysteine. Candida species, which are yeasts, use CUG (leucine) for serine. Other departures from the universal code, all in nonplant mitochondria, are CUN (leucine) for threonine (in yeasts), AAA (lysine) for asparagine (in platyhelminths and echinoderms), UAA (stop) for tyrosine (in planaria), and AGR (arginine) for serine (in several animal orders) and for stop (in vertebrates). We propose that the changes are typically preceded by loss of a codon from all coding sequences in an organism or organelle, often as a result of directional mutation pressure, accompanied by loss of the tRNA that translates the codon. The codon reappears later by conversion of another codon and emergence of a tRNA that translates the reappeared codon with a different assignment. Changes in release factors also contribute to these revised assignments. We also discuss the use of UGA (stop) as a selenocysteine codon and the early history of the code.

Superoxide dismutase activity and superoxide dismutase-1 gene methylation in normal and tumoral human breast tissues

The superoxide dismutase (SOD) activities in normal and tumor breast tissues from 14 human females were determined by the epinephrine autoxidation assay. SOD levels showed a marked interindividual variability in normal and malignant cells. However, each donor had a higher SOD activity in cancer than in normal tissue samples. In three cases in which Mn- and CuZnSOD activities were determined, it was found that tumoral increases in SOD were due to increases in both enzymatic forms. Therefore, it seems reasonable to assume a similar situation for all cases in our series. The level of DNA methylation in the SOD-1 gene was assessed in the first four donors. The four cases exhibited full methylation of SOD-1 genes corresponding to normal as well as to cancer cells. It is concluded that the variability in CuZnSOD activities is not related with the state of methylation of the SOD-1 gene. MspI restriction fragment polymorphisms between DNA samples from normal and malignant cells were detected in the four DNA donors. This phenomenon may be due to point mutations changing the frequency of MspI sites or to methylation of the external C in CCGG sequences.

mTFE3, an X-linked transcriptional activator containing basic helix-loop-helix and zipper domains, utilizes the zipper to stabilize both DNA binding and multimerization

Southwestern (DNA-protein) screening of a murine L-cell cDNA library by using a probe for the microE3 site in the immunoglobulin heavy-chain enhancer yielded a clone, mTFE3, which is a member of the subset of basic helix-loop-helix (BHLH) proteins that also contain a leucine zipper (ZIP). Since the individual contribution of these domains is not well understood for proteins which contain them both, mutational analyses were performed to assess the functional roles of the HLH and ZIP regions for DNA binding and multimerization. The HLH region is stringently required for DNA binding but not for multimerization. The ZIP region is not stringently required for binding or multimerization, but stabilizes both multimer formation and DNA binding. A high degree of conservation at both the amino acid and nucleotide levels between the human transcription factor TFE3 and mTFE3 suggests that mTFE3 is the murine homolog of human TFE3. By using fluorescent in situ hybridization, mTFE3 was mapped to mouse chromosome X in band A2, which is just below the centromere. We show that in addition to the immunoglobulin heavy-chain microE3 site, mTFE3 binds to transcriptional elements important for lymphoid-specific, muscle-specific, and ubiquitously expressed genes. Binding of mTFE3 to DNA induces DNA bending.

mTFE3, an X-linked transcriptional activator containing basic helix-loop-helix and zipper domains, utilizes the zipper to stabilize both DNA binding and multimerization

Southwestern (DNA-protein) screening of a murine L-cell cDNA library by using a probe for the microE3 site in the immunoglobulin heavy-chain enhancer yielded a clone, mTFE3, which is a member of the subset of basic helix-loop-helix (BHLH) proteins that also contain a leucine zipper (ZIP). Since the individual contribution of these domains is not well understood for proteins which contain them both, mutational analyses were performed to assess the functional roles of the HLH and ZIP regions for DNA binding and multimerization. The HLH region is stringently required for DNA binding but not for multimerization. The ZIP region is not stringently required for binding or multimerization, but stabilizes both multimer formation and DNA binding. A high degree of conservation at both the amino acid and nucleotide levels between the human transcription factor TFE3 and mTFE3 suggests that mTFE3 is the murine homolog of human TFE3. By using fluorescent in situ hybridization, mTFE3 was mapped to mouse chromosome X in band A2, which is just below the centromere. We show that in addition to the immunoglobulin heavy-chain microE3 site, mTFE3 binds to transcriptional elements important for lymphoid-specific, muscle-specific, and ubiquitously expressed genes. Binding of mTFE3 to DNA induces DNA bending.

Genome canalization: the coevolution of transposable and interspersed repetitive elements with single copy DNA

Transposable and interspersed repetitive elements (TIREs) are ubiquitous features of both prokaryotic and eukaryotic genomes. However, controversy has arisen as to whether these sequences represent useless 'selfish' DNA elements, with no cellular function, as opposed to useful genetic units. In this review, we selected two insect species, the Dipteran Drosophila and the Lepidopteran Bombyx mori (the silkmoth), in an attempt to resolve this debate. These two species were selected on the basis of the special interest that our laboratory has had over the years in Bombyx with its well known molecular and developmental biology, and the wealth of genetic data that exist for Drosophila. In addition, these two species represent contrasting repetitive element types and patterns of distribution. On one hand, Bombyx exhibits the short interspersion pattern in which Alu-like TIREs predominate while Drosophila possesses the long interspersion pattern in which retroviral-like TIREs are prevalent. In Bombyx, the main TIRE family is Bm-1 while the Drosophila group contains predominantly copia-like elements, non-LTR retroposons, bacterial-type retroposons and fold-back transposable elements sequences. Our analysis of the information revealed highly non-random patterns of both TIRE biology and evolution, more indicative of these sequences acting as genomic symbionts under cellular regulation rather than useless or selfish junk DNA. In addition, we extended our analysis of potential TIRE functionality to what is known from other eukaryotic systems. From this study, it became apparent that these DNA elements may have originated as innocuous or selfish sequences and then adopted functions. The mechanism for this conversion from non-functionality to specific roles is a process of coevolution between the repetitive element and other cellular DNA often times in close physical proximity. The resulting interdependence between repetitive elements and other cellular sequences restrict the number of evolutionarily successful mutational changes for a given function or cistron. This mutual limitation is what we call genome canalization. Well documented examples are discussed to support this hypothesis and a mechanistic model is presented for how such genomic canalization can occur. Also proposed are empirical studies which would support or invalidate aspects of this hypothesis.