Thermal stability of human DNA and chimpanzee DNA heteroduplexes.

The base pairing fidelity of heteroduplexes formed from human DNA and chimpanzee DNA has been studied by the criterion of thermal stability to test the evolutionary conservation of repeated DNA base sequences.

Master genes in mammalian repetitive DNA amplification.

The analysis of species-specific subfamilies of both the LINE and SINE mammalian repetitive DNA families suggests that such subfamilies have arisen by amplification of an extremely small group of 'master' genes. In contrast to the master genes, the vast majority of both SINEs and LINEs appear to behave like psudogenes in their inability to undergo extensive amplification.

Recently amplified Alu family members share a common parental Alu sequence.

Three of the most recently inserted primate Alu family members are exceptionally closely related. Therefore, one, or a few, Alu family members are dominating the amplification process and the vast majority are not actively involved in retroposition. Although individual Alu family members are not under any apparent evolutionary constraint, the sequences of these active members are being moderately conserved.

Human thymidine kinase gene: molecular cloning and nucleotide sequence of a cDNA expressible in mammalian cells.

A cDNA containing the entire coding region of the human thymidine kinase gene has been molecularly cloned. The cDNA is under the control of a simian virus 40 promoter and is expressible in mammalian cells. The complete nucleotide sequence of the human thymidine kinase cDNA has been determined. The cDNA is 1,421 base pairs in length and has a large open reading frame of 702 base pairs capable of specifying a protein with a molecular weight of 25,504. Genomic Southern blotting experiments show that sequences homologous to the human thymidine kinase cDNA are conserved among many vertebrates, including prosimians (lemur), tree shrews, rats, mice, and chickens. Direct comparison of the nucleotide sequences of the human thymidine kinase cDNA and the chicken thymidine kinase gene reveals ca. 70% overall homology. This homology is extended further at the amino acid sequence level, with greater than 74% amino acid residues matched between the human and chicken thymidine kinase proteins.

Gene conversion as a secondary mechanism of short interspersed element (SINE) evolution.

The Alu repetitive family of short interspersed elements (SINEs) in primates can be subdivided into distinct subfamilies by specific diagnostic nucleotide changes. The older subfamilies are generally very abundant, while the younger subfamilies have fewer copies. Some of the youngest Alu elements are absent in the orthologous loci of nonhuman primates, indicative of recent retroposition events, the primary mode of SINE evolution. PCR analysis of one young Alu subfamily (Sb2) member found in the low-density lipoprotein receptor gene apparently revealed the presence of this element in the green monkey, orangutan, gorilla, and chimpanzee genomes, as well as the human genome. However, sequence analysis of these genomes revealed a highly mutated, older, primate-specific Alu element was present at this position in the nonhuman primates. Comparison of the flanking DNA sequences upstream of this Alu insertion corresponded to evolution expected for standard primate phylogeny, but comparison of the Alu repeat sequences revealed that the human element departed from this phylogeny. The change in the human sequence apparently occurred by a gene conversion event only within the Alu element itself, converting it from one of the oldest to one of the youngest Alu subfamilies. Although gene conversions of Alu elements are clearly very rare, this finding shows that such events can occur and contribute to specific cases of SINE subfamily evolution.

Characterization of myelin proteolipid mRNAs in normal and jimpy mice.

A clone specific for the rat myelin proteolipid protein (PLP) was isolated from a cDNA library made in pUC18 from 17-day-old rat brain stem mRNA. This clone corresponded to the carboxyl-terminal third of the PLP-coding region. The clone was used to identify PLP-specific mRNAs in mouse brain and to establish the time course of PLP mRNA expression during mouse brain development. Three PLP-specific mRNAs were seen, approximately 1,500, 2,400, and 3,200 bases in length, of which the largest was the most abundant. During brain development, the maximal period of PLP mRNA expression was from 14 to 25 days of age, and this was a similar time course to that for myelin basic protein mRNA expression. When the jimpy mouse, an X-linked dysmyelination mutant, was studied for PLP mRNA expression, low levels of PLP mRNA were seen which were approximately 5% of wild-type levels at 20 days of age. When jimpy brain RNA was analyzed by Northern blotting, the PLP-specific mRNA was shown to be 100 to 200 bases shorter than the wild-type PLP-specific mRNA. This size difference was seen in the two major PLP mRNAs, and it did not result from a loss of polyadenylation of these mRNAs.

Dominant negative mutants of transforming growth factor-beta 1 inhibit the secretion of different transforming growth factor-beta isoforms.

Transforming growth factor-beta (TGF-beta) is a secreted polypeptide factor that is thought to play a major role in the regulation of proliferation of many cell types and various differentiation processes. Several related isoforms have been structurally characterized, three of which, TGF-beta 1, -beta 2, and -beta 3, have been detected in mammalian cells and tissues. Each TGF-beta form is a homodimer of a 112-amino-acid polypeptide which is encoded as a larger polypeptide precursor. We have introduced several mutations in the TGF-beta 1 precursor domain, resulting in an inhibition of TGF-beta 1 secretion. Coexpression of these mutants with wild-type TGF-beta 1, -beta 2, and -beta 3 results in a competitive and specific inhibition of the secretion of different TFG-beta forms, indicating that these mutated versions act as dominant negative mutants for TGF-beta secretion. Overexpression of dominant negative mutants can thus be used to abolish endogenous secretion of TGF-beta and structurally related family members, both in vitro and in vivo, and to probe in this way the physiological functions of the members of the TGF-beta superfamily.

Inviting instability: Transposable elements, double-strand breaks, and the maintenance of genome integrity.

The ubiquity of mobile elements in mammalian genomes poses considerable challenges for the maintenance of genome integrity. The predisposition of mobile elements towards participation in genomic rearrangements is largely a consequence of their interspersed homologous nature. As tracts of nonallelic sequence homology, they have the potential to interact in a disruptive manner during both meiotic recombination and DNA repair processes, resulting in genomic alterations ranging from deletions and duplications to large-scale chromosomal rearrangements. Although the deleterious effects of transposable element (TE) insertion events have been extensively documented, it is arguably through post-insertion genomic instability that they pose the greatest hazard to their host genomes. Despite the periodic generation of important evolutionary innovations, genomic alterations involving TE sequences are far more frequently neutral or deleterious in nature. The potentially negative consequences of this instability are perhaps best illustrated by the >25 human genetic diseases that are attributable to TE-mediated rearrangements. Some of these rearrangements, such as those involving the MLL locus in leukemia and the LDL receptor in familial hypercholesterolemia, represent recurrent mutations that have independently arisen multiple times in human populations. While TE-instability has been a potent force in shaping eukaryotic genomes and a significant source of genetic disease, much concerning the mechanisms governing the frequency and variety of these events remains to be clarified. Here we survey the current state of knowledge regarding the mechanisms underlying mobile element-based genetic instability in mammals. Compared to simpler eukaryotic systems, mammalian cells appear to have several modifications to their DNA-repair ensemble that allow them to better cope with the large amount of interspersed homology that has been generated by TEs. In addition to the disruptive potential of nonallelic sequence homology, we also consider recent evidence suggesting that the endonuclease products of TEs may also play a key role in instigating mammalian genomic instability.

Cis-acting influences on Alu RNA levels.

The human short interspersed repeated element (SINE), Alu, amplifies through a poorly understood RNA-mediated mechanism, termed retroposition. There are over one million copies of Alu per haploid human genome. The copies show some internal variations in sequence and are very heterogeneous in chromosomal environment. However, very few Alu elements actively amplify. The amplification rate has decreased greatly in the last 40 million years. Factors influencing Alu transcription would directly affect an element's retroposition capability. Therefore, we evaluated several features that might influence expression from individual Alu elements. The influence of various internal sequence variations and 3' unique flanks on full-length Alu RNA steady-state levels was determined. Alu subfamily diagnostic mutations do not significantly alter the amount of Alu RNA observed. However, sequences containing random mutations throughout the right half of selected genomic Alu elements altered Alu RNA steady-state levels in cultured cells. In addition, sequence variations at the 3' unique end of the transcript also significantly altered the Alu RNA levels. In general, sequence mutations and 3' end sequences contribute to Alu RNA levels, suggesting that the master Alu element(s) have a multitude of individual differences that collectively gives them a selective advantage over other Alu elements.

A critical examination of possible fractionations of human DNA according to base composition.

Human DNA has been fractionated according to base composition by sedimentation equilibrium in an HgCl2/Cs2SO4 density gradient, followed by sedimentation equilibrium in an actinomycin/cesium formate density gradient. The fractions of different base composition resulting from this procedure were subsequently analyzed by sedimentation equilibrium in CsCl, DNA renaturation kinetics, and electron microscopy. All fractions contain similar kinetic classes of repeated DNA sequences as judged by renaturation studies. Short (300 nucleotides) interspersed repeated sequences are found in all fractions with no noticeable enrichment for these sequences in any fraction. Repeated sequences from fractions of different base composition are partially able to cross-hybridize, demonstrating that nearly identical repeated sequences occur in molecules of different base composition. These findings are critically compared to reports of successful density gradient fractionations of different human DNA sequence classes.

Identification and analysis of a 'young' polymorphic Alu element.

A polymorphic Alu element belonging to a young subfamily of Alu repeats has been identified. Sequence analysis showed that this Alu element is flanked by perfect direct repeats and a 3' oligo(dA)-rich tail. The Alu element, designated A25, is deleted by 34 nucleotides at the 5' end and has a single CpG mutation compared to the human-specific consensus sequence. Using a PCR-based assay, we demonstrated that the A25 Alu repeat is localized to human chromosome 8 and is polymorphic in humans.

Assembly of a high-resolution map of the Acadian Usher syndrome region and localization of the nuclear EF-hand acidic gene.

Usher syndrome type 1C (USH1C) occurs in a small population of Acadian descendants from southwestern Louisiana. Linkage and linkage disequilibrium analyses localize USH1C to chromosome 11p between markers D11S1397 and D11S1888, an interval of less than 680 kb. Here, we refine the USH1C linkage to a region less than 400 kb, between genetic markers D11S1397 and D11S1890. Using 17 genetic markers from this interval, we have isolated a contiguous set of 60 bacterial artificial chromosomes (BACs) that span the USH1C critical region. Exon trapping of BAC clones from this region resulted in the recovery of an exon of the nuclear EF-hand acidic (NEFA) gene. However, DNA sequence analysis of the NEFA cDNA from lymphocytes of affected individuals provided no evidence of mutation, making structural mutations in the NEFA protein unlikely as the cellular cause of Acadian Usher syndrome.

The mouse deafness locus (dn) is associated with an inversion on chromosome 19.

Recombination data for the mouse deafness locus (dn) on chromosome 19 are consistent with the presence of an inversion for which one of the breakpoints is between D19Mit14 and D19Mit96, a distance of less than 226 kb. Fluorescence in situ hybridization studies using a bacterial artificial chromosome on interphase (G1) nuclei provide additional support for the presence of an inversion. The dn gene is probably the orthologue of the human DFNB7/DFNB11 gene on chromosome 9.

Human retroelements may introduce intragenic polyadenylation signals.

In the human genome, the insertion of LINE-1 and Alu elements can affect genes by sequence disruption, and by the introduction of elements that modulate the gene's expression. One of the modulating sequences retroelements may contribute is the canonical polyadenylation signal (pA), AATAAA. L1 elements include these within their own sequence and AATAAA sequences are commonly created in the A-rich tails of both SINEs and LINEs. Computational analysis of 34 genes randomly retrieved from the human genome draft sequence reveals an orientation bias, reflected as a lower number of L1s and Alus containing the pA in the same orientation as the gene. Experimental studies of Alu-based pA sequences when placed in pol II or pol III transcripts suggest that the signal is very weak, or often not used at all. Because the pA signal is highly affected by the surrounding sequence, it is likely that the Alu constructs evaluated did not provide the required recognition signals to the polyadenylation machinery. Although the effect of pA signals contributed by Alus is individually weak, the observed reduction of "sense" oriented pA-containing L1 and Alu elements within genes reflects that even a modest influence causes a change in evolutionary pressure, sufficient to create the biased distribution.

Recent amplification of rat ID sequences.

The rodent identifier (ID) family of repeats has amplified at an extremely high rate in the rat genome in recent evolutionary time, resulting in 130,000 copies per haploid genome. Statistical analyses support the grouping of 119 individual rat ID elements into four major and three minor subfamilies based on six diagnostic nucleotide positions. The consensus sequence of the oldest subfamily is identical to the ID region of the rat BC1 RNA gene, suggesting that the BC1 gene has dominated the early amplification of rat ID elements. The other six subfamilies share at least one diagnostic mutation in relation to the BC1 gene and show much less nucleotide sequence divergence, indicating that the recent large amplification of rat ID elements has been driven by another lineage of master gene(s) in the rat genome. This is consistent with the formation of a new lineage of master elements for ID amplification in rat. The formation of most rat ID elements appears to have occurred during the past three million years based on the results that four out of five randomly chosen ID elements are present only in the genome of one rat species and not in other closely related species.

cDNAs derived from primary and small cytoplasmic Alu (scAlu) transcripts.

We have isolated and sequenced twenty-six cDNAs derived from primary Alu transcripts. Most cDNAs (22/26) sequenced end in multiple T residues, known to be at the termination for RNA polymerase III-directed transcripts. We conclude that these cDNAs were derived from authentic, RNA polymerase III-directed primary Alu transcripts. Sequence alignment of the cDNAs with Alu consensus sequences show that the cDNAs belong to different, previously described Alu subfamilies. The sequence variation observed in the 3' non-Alu regions of each of the cDNAs led us to conclude that they were derived from different genomic loci, thus demonstrating that multiple Alu loci are transcriptionally active. The subfamily distribution of the cDNAs suggests that transcriptional activity is biased towards evolutionarily younger Alu subfamilies, with a strong selection for the consensus sequence in the first 42 bases and the promoter B box. Sequence data from seven cDNAs derived from small cytoplasmic Alu (scAlu) transcripts, a processed form of Alu transcripts, also have a similar bias towards younger Alu subfamilies. About half of these cDNAs are due to processing or degradation, but the other half appear to be due to the formation of a cryptic RNA polymerase III termination signal in multiple loci. Using our sequence data, we have isolated a transcriptionally active genomic Alu element belonging to the Ya5 subfamily. In vitro transcription studies of this element suggest that its flanking sequences contribute to its transcriptional activity. The role of flanking sequences and other factors involved in transcriptional activity of Alu elements are discussed.

Upstream flanking sequences and transcription of SINEs.

SINEs, short interspersed repeated DNA elements, undergo amplification through retroposition and subsequent integration into a new location in the genome. Each new SINE insertion will be located in a new chromosomal environment, with different flanking sequences. Modulation of transcription by different flanking sequences may play an important role in determining which SINE elements are preferentially active in a genome. We evaluated the ability of upstream flanking sequences to regulate the transcription of three different SINEs (Alu, B2 and ID) by constructing chimeric constructs with known 5' flanking sequences of RNA polymerase III-transcribed genes. Upstream sequences from the 7SL RNA gene, U6 RNA gene, vault RNA gene, and BC1 gene increase transcription of Alu, B2 and BC1 in transient transfections of NIH3T3, HeLa, Neuro2a and C6 glioma cell lines. The 7SL sequence proved most efficient in increasing SINE transcription. The 7SL upstream fused to the BC1 RNA gene (an ID element) was used to create a transgenic mouse line. In contrast to the tissue-specific endogenous BC1 transcription, BC1 transgene transcripts were detected in all tissues tested. However, expression was much higher in those tissues that express the endogenous gene, demonstrating both transcriptional and post-transcriptional regulation. The BC1 RNA was detected in a similar ribonucleoprotein complex in the different tissues.

Dispersion and insertion polymorphism in two small subfamilies of recently amplified human Alu repeats.

Newly isolated members of two recently propagated (young) Alu subfamilies were examined for sequence diversity and insertion polymorphism in primate genomes. The smaller subfamily (termed HS-2) is comprised of approximately 5 to 25 members, while the larger (termed Sb2) includes approximately 125 to 600 members. Individual members of these Alu subfamilies share distinguishing sets of diagnostic mutations, are well-conserved relative to each other, and have expanded in the human lineage. At least one member from each subfamily is known to be polymorphic in humans. Three newly characterized HS-2 Alu family members as well as three Sb2 Alu repeats are monomorphic (fixed) in humans. The existence of a number of Alu subfamilies that have amplified in parallel within the human genome provides compelling evidence for the simultaneous activity of multiple dispersed Alu source genes.

Large-scale analysis of the Alu Ya5 and Yb8 subfamilies and their contribution to human genomic diversity.

We have utilized computational biology to screen GenBank for the presence of recently integrated Ya5 and Yb8 Alu family members. Our analysis identified 2640 Ya5 Alu family members and 1852 Yb8 Alu family members from the draft sequence of the human genome. We selected a set of 475 of these elements for detailed analyses. Analysis of the DNA sequences from the individual Alu elements revealed a low level of random mutations within both subfamilies consistent with the recent origin of these elements within the human genome. Polymerase chain reaction assays were used to determine the phylogenetic distribution and human genomic variation associated with each Alu repeat. Over 99 % of the Ya5 and Yb8 Alu family members were restricted to the human genome and absent from orthologous positions within the genomes of several non-human primates, confirming the recent origin of these Alu subfamilies in the human genome. Approximately 1 % of the analyzed Ya5 and Yb8 Alu family members had integrated into previously undefined repeated regions of the human genome. Analysis of mosaic Yb8 elements suggests gene conversion played an important role in generating sequence diversity among these elements. Of the 475 evaluated elements, a total of 106 of the Ya5 and Yb8 Alu family members were polymorphic for insertion presence/absence within the genomes of a diverse array of human populations. The newly identified Alu insertion polymorphisms will be useful tools for the study of human genomic diversity.

Alu insertion polymorphisms for the study of human genomic diversity.

Genomic database mining has been a very useful aid in the identification and retrieval of recently integrated Alu elements from the human genome. We analyzed Alu elements retrieved from the GenBank database and identified two new Alu subfamilies, Alu Yb9 and Alu Yc2, and further characterized Yc1 subfamily members. Some members of each of the three subfamilies have inserted in the human genome so recently that about a one-third of the analyzed elements are polymorphic for the presence/absence of the Alu repeat in diverse human populations. These newly identified Alu insertion polymorphisms will serve as identical-by-descent genetic markers for the study of human evolution and forensics. Three previously classified Alu Y elements linked with disease belong to the Yc1 subfamily, supporting the retroposition potential of this subfamily and demonstrating that the Alu Y subfamily currently has a very low amplification rate in the human genome.