Maintenance of function without selection: Alu sequences as "cheap genes"

The role of SRP9/SRP14 in regulating Alu RNA

SRP9/SRP14 is a protein heterodimer that plays a critical role in the signal recognition particle through its interaction with the scaffolding signal recognition particle RNA (7SL). SRP9/SRP14 binding to 7SL is mediated through a conserved structural motif that is shared with the primate-specific Alu RNA. Alu RNA are transcription products of Alu elements, a retroelement that comprises ~10% of the human genome. Alu RNA are involved in myriad biological processes and are dysregulated in several human disease states. This review focuses on the roles SRP9/SRP14 has in regulating Alu RNA diversification, maturation, and function. The diverse mechanisms through which SRP9/SRP14 regulates Alu RNA exemplify the breadth of protein-mediated regulation of non-coding RNA.

ALUminating the Path of Atherosclerosis Progression: Chaos Theory Suggests a Role for Alu Repeats in the Development of Atherosclerotic Vascular Disease

Atherosclerosis (ATH) and coronary artery disease (CAD) are chronic inflammatory diseases with an important genetic background; they derive from the cumulative effect of multiple common risk alleles, most of which are located in genomic noncoding regions. These complex diseases behave as nonlinear dynamical systems that show a high dependence on their initial conditions; thus, long-term predictions of disease progression are unreliable. One likely possibility is that the nonlinear nature of ATH could be dependent on nonlinear correlations in the structure of the human genome. In this review, we show how chaos theory analysis has highlighted genomic regions that have shared specific structural constraints, which could have a role in ATH progression. These regions were shown to be enriched with repetitive sequences of the Alu family, genomic parasites that have colonized the human genome, which show a particular secondary structure and are involved in the regulation of gene expression. Here, we show the impact of Alu elements on the mechanisms that regulate gene expression, especially highlighting the molecular mechanisms via which the Alu elements alter the inflammatory response. We devote special attention to their relationship with the long noncoding RNA (lncRNA); antisense noncoding RNA in the INK4 locus (ANRIL), a risk factor for ATH; their role as microRNA (miRNA) sponges; and their ability to interfere with the regulatory circuitry of the (nuclear factor kappa B) NF-κB response. We aim to characterize ATH as a nonlinear dynamic system, in which small initial alterations in the expression of a number of repetitive elements are somehow amplified to reach phenotypic significance.

CORE-SINEs: eukaryotic short interspersed retroposing elements with common sequence motifs

A 65-bp "core" sequence is dispersed in hundreds of thousands copies in the human genome. This sequence was found to constitute the central segment of a group of short interspersed elements (SINEs), referred to as mammalian-wide interspersed repeats, that proliferated before the radiation of placental mammals. Here, we propose that the core identifies an ancient tRNA-like SINE element, which survived in different lineages such as mammals, reptiles, birds, and fish, as well as mollusks, presumably for >550 million years. This element gave rise to a number of sequence families (CORE-SINEs), including mammalian-wide interspersed repeats, whose distinct 3' ends are shared with different families of long interspersed elements (LINEs). The evolutionary success of the generic CORE-SINE element can be related to the recruitment of the internal promoter from highly transcribed host RNA as well as to its capacity to adapt to changing retropositional opportunities by sequence exchange with actively amplifying LINEs. It reinforces the notion that the very existence of SINEs depends on the cohabitation with both LINEs and the host genome.

Junk DNA and sectorial gene repression

Transcriptional repression in eukaryotes often involves tens or hundreds of kilobase pairs, two to three orders of magnitude more than the bacterial operator/repressor model does. Classical repression, represented by this model, was maintained over the whole span of evolution under different guises, and consists of repressor factors interacting primarily with promoters and, in later evolution, also with enhancers. The use of much larger amounts of DNA in the other mode of repression, here called the sectorial mode ('superrepression'), results in the conceptual transfer of so-called junk DNA to the domain of functional DNA. This contribution to the solution of the c-value paradox involves perhaps 15% of genomic 'junk,' and encompasses the bulk of the introns, thought to fill a stabilizing role in sectorially repressed chromatin structures. In the case of developmental genes, such structures appear to be heterochromatoid in character. However, solid clues regarding general structural features of superrepressed terminal differentiation genes remain elusive. The competition among superrepressible DNA sectors for sectorially binding factors offers, in principle, a molecular mechanism for developmental switches. Position effect variegation may be considered an abnormal manifestation of normal processes that underly development and involve heterochromatoid sectorial repression, which is apparently required for local elimination or modulation of morphological features (morpholysis). Sectorial repression of genes participating either in development or in terminal differentiation is considered instrumental in establishing stable cell types, and provides a basis for the distinction between determination and cell type specification. The gamut of possible stable cell types may have been broadened by the appearance in evolution of heavy isochores. Additional types of relatively frequent GC-rich cis-acting DNA motifs may offer reiterated binding sites to factors endowed with a selective (though not individually strong) affinity for these motifs. The majority of sequence motifs thought to be used in superrepression need not be individually maintained by natural selection. It is re-emphasized that the dispensability of sequences is not an indicator of their nonfunctionality and that in many cases, along noncoding sequences, nucleotides tend to fill functions collectively, rather than individually.

A dimorphic Alu Sb-like insertion in COL3A1 is ethnic-specific

Alu elements are a class of repetitive DNA sequences found throughout the human genome that are thought to be duplicated via an RNA intermediate in a process termed retroposition. Recently inserted Alu elements are closely related, suggesting that they are derived from a single source gene or closely related source genes. Analysis of the type III collagen gene (COL3A1) revealed a polymorphic Alu insertion in intron 8 of the gene. The Alu insertion in the COL3A1 gene had a high degree of nucleotide identity to the Sb family of Alu elements, a family of older Alu elements. The Alu sequence was less similar to the consensus sequence for the PV or Sb2 subfamilies, subfamilies of recently inserted Alu elements. These data support the observations that at least three source genes are active in the human genome, one of which is distinct from the PV and Sb2 subfamilies and predates either of these two subfamilies. Appearance of the Alu insertion in different ethnic populations suggests that the insertion may have occurred in the last 100,000 years. This Alu insert should be a useful marker for population studies and for marking COL3A1 alleles.

Polymorphic human specific Alu insertions as markers for human identification

Alu sequences represent the largest family of short interspersed repetitive elements (SINEs) in humans with 500 000 copies per genome. Recently, one Alu subfamily was found to be human specific (HS). We originally described the use of polymorphis HS Alu insertions as a tool in population studies and recently as tools in DNA fingerprinting and forensic analysis. In this report, we will use this simple polymerase chain reaction (PCR) base technique for the detection of HS Alu insertion polymorphisms. We will test the resolving power of this DNA profiling approach in both population genetics and paternity assessment. At the population level, we will describe the genotypic distribution of five polymorphic Alu insertions among 3 populations from the American continent, one of African origin, the other two Amerindians. Insight into their relationships will be provided. At the family level, we will examine one European American family of seven individuals and the same pedigree will also be characterized by way of the two systems currently and widely used to ascertain paternity: PCR-sequence specific oligonucleotide probe hybridization (PCR-SSO) and PCR-restriction fragment length polymorphism (PCR-RFLP) of human leucocyte antigen (HLA) class II molecules, and a standard RFLP protocol used in forensic casework and paternity studies. The importance and strengths of the methods as well as its perspectives for future use in filiation studies will be evaluated.

An arrayed library enriched in hncDNA corresponding to transcribed sequences of human chromosome 19: preparation and analysis

A simple technique for preparation of libraries of the human chromosome specific transcribed sequences is developed. It uses hnRNA from human-rodent hybrid cell lines containing particular human chromosomes or their fragments and includes three stages: (i) reverse transcription of the hnRNA with Alu-specific primers directing the transcription beyond the Alu-repeats to flanking non-repetitive sequences of the chromosome; (ii) nested primer PCR strategy with specifically designed primers; (iii) direct selective cloning of the second-stage nested primer PCR products. An arrayed hncDNA library was prepared from a hybrid cell line containing chromosome 19 and fragments of 22 and X chromosomes. The library contains around 98% of human-specific transcribed sequences. Sequences of 52 human-specific, according to PCR analysis, clones differed from each other and had no close analogs in the EMBL Data Bank. Of 17 clones assigned to certain human chromosomes, 9 belonged to chromosome 19, 5 to chromosome 22 and 3 to chromosome X. Some of the human specific clones contained repetitive elements scattered over different human chromosomes. Clones from hncDNA libraries are useful as STSs/ESTs, as probes for detecting full-size genes in genomic libraries, for RFLP analysis and for identification of chromosome specific cDNAs.

Mapping of transcribed sequences on human chromosome 19

30 EST/STS have been mapped on human chromosome 19 using a highly specific hncDNA library as a source of transcribed sequences. In addition more than 50 sites constituting 19 families of closely related sequences containing at least one transcribed member each were mapped across the chromosome. Chromosome-19 specific hncDNA clones were hybridized to chromosome 19 cosmids that were previously assembled into contigs covering about 80% of Chr19. The hybridization results were verified by PCR. Such an approach to EST mapping provides information on possible locations of genes as transcribed units of genome and on location of repeated elements used for the priming the hncDNA synthesis. Mapped hncDNA sequences may serve as good starting points for the systematic sequencing of transcribed genomic regions.

Alu elements of the primate major histocompatibility complex

The chromosomal region constituting the major histocompatibility complex (MHC) has undergone complex evolution that is often difficult to decipher. An important aid in the elucidation of the MHC evolution is the presence of Alu elements (repeats) which serve as markers for tracing chromosomal rearrangements. As the first step toward the establishment of sets of evolutionary markers for the MHC, Alu elements present in selected MHC haplotypes of the human species, the gorilla, and the chimpanzee were identified. Restriction fragments of cosmid clones from the libraries of the three species were hybridized with Alu-specific probes, Alu elements were amplified by the polymerase chain reaction, and the amplification products were sequenced. In some cases, sequences of the regions flanking the Alu elements were also obtained. Altogether, 31 new Alu elements were identified, representing six Alu subfamilies. The average density of Alu elements in the MHC is one element per four kilobases (kb) of sequence. Alu elements have apparently been inserted steadily into the MHC over the last 65 million years (my). On average, one Alu element is inserted into the primate MHC every 4 my. Analysis of the human DR3 haplotype supports its origin by duplication from an ancestral haplotype consisting of DRB1 and DRB2 genes. The sharing of an old Alu element by the DRB1 and DRB2 genes, in turn, supports their divergence from a common ancestor more than 55 my ago.

A human Alu RNA-binding protein whose expression is associated with accumulation of small cytoplasmic Alu RNA

Human Alu sequences are short interspersed DNA elements which have been greatly amplified by retrotransposition. Although initially derived from the 7SL RNA component of signal recognition particle (SRP), the Alu sequence has evolved into a dominant transposon while retaining a specific secondary structure found in 7SL RNA. We previously characterized a set of Alu sequences which are expressed as small cytoplasmic RNAs and isolated a protein that binds to these transcripts. Here we report that biochemical purification of this protein revealed it as the human homolog of the SRP 14 polypeptide which binds the Alu-homologous region of 7SL RNA. The human cDNA predicts an alanine-rich C-terminal tail translated from a trinucleotide repeat not found in the rodent homolog, which accounts for why the human protein-RNA complex migrates more slowly than its rodent counterpart in RNA mobility shift assays. The human Alu RNA-binding protein (RBP) is expressed after transfection of this cDNA into mouse cells. Expression of human RBP in rodent x human somatic cell hybrids is associated with substantial increase in endogenous small cytoplasmic Alu and scB1 transcripts but not other small RNAs. These studies provide evidence that this RBP associates with Alu transcripts in vivo and affects their metabolism and suggests a role for Alu transcripts in translation in an SRP-like manner. Analysis of hybrid lines indicated that the Alu RBP gene maps to human chromosome 15q22, which was confirmed by Southern blotting. The possibility that the primate-specific structure of this protein may have contributed to Alu evolution is considered.

A human Alu RNA-binding protein whose expression is associated with accumulation of small cytoplasmic Alu RNA

Human Alu sequences are short interspersed DNA elements which have been greatly amplified by retrotransposition. Although initially derived from the 7SL RNA component of signal recognition particle (SRP), the Alu sequence has evolved into a dominant transposon while retaining a specific secondary structure found in 7SL RNA. We previously characterized a set of Alu sequences which are expressed as small cytoplasmic RNAs and isolated a protein that binds to these transcripts. Here we report that biochemical purification of this protein revealed it as the human homolog of the SRP 14 polypeptide which binds the Alu-homologous region of 7SL RNA. The human cDNA predicts an alanine-rich C-terminal tail translated from a trinucleotide repeat not found in the rodent homolog, which accounts for why the human protein-RNA complex migrates more slowly than its rodent counterpart in RNA mobility shift assays. The human Alu RNA-binding protein (RBP) is expressed after transfection of this cDNA into mouse cells. Expression of human RBP in rodent x human somatic cell hybrids is associated with substantial increase in endogenous small cytoplasmic Alu and scB1 transcripts but not other small RNAs. These studies provide evidence that this RBP associates with Alu transcripts in vivo and affects their metabolism and suggests a role for Alu transcripts in translation in an SRP-like manner. Analysis of hybrid lines indicated that the Alu RBP gene maps to human chromosome 15q22, which was confirmed by Southern blotting. The possibility that the primate-specific structure of this protein may have contributed to Alu evolution is considered.

Multiple dispersed loci produce small cytoplasmic Alu RNA

Alu repeats are short interspersed elements (SINEs) of dimeric structure whose transposition sometimes leads to heritable disorders in humans. Human cells contain a poly(A)- small cytoplasmic transcript of -120 nucleotides (nt) homologous to the left Alu monomer. Although its monomeric size indicates that small cytoplasmic Alu (scAlu) RNA is not an intermediary of human Alu transpositions, a less abundant poly(A)-containing Alu transcript of dimeric size and specificity expected of a transposition intermediary is also detectable in HeLa cells (A. G. Matera, U. Hellmann, M. F. Hintz, and C. W. Schmid, Mol. Cell. Biol. 10:5424-5432, 1990). Although its function is unknown, the accumulation of Alu RNA and its ability to interact with a conserved protein suggest a role in cell biology (D.-Y. Chang and R. J. Maraia, J. Biol. Chem. 268:6423-28, 1993). The relationship between the -120- and -300-nt Alu transcripts had not been determined. However, a B1 SINE produces scB1 RNA by posttranscriptional processing, suggesting a similar pathway for scAlu. An Alu SINE which recently transposed into the neurofibromatosis 1 locus was expressed in microinjected frog oocytes. This neurofibromatosis 1 Alu produced a primary transcript followed by the appearance of the scAlu species. 3' processing of a synthetic -300-nt Alu RNA by HeLa nuclear extract in vitro also produced scAlu RNA. Primer extension of scAlu RNA indicates synthesis by RNA polymerase III. HeLa-derived scAlu cDNAs were cloned so as to preserve their 5'-terminal sequences and were found to correspond to polymerase III transcripts of the left monomeric components of three previously identified Alu SINE subfamilies. Rodent x human somatic cell hybrids express Alu RNAs whose size, heterogeneous length, and chromosomal distribution indicate their derivation from SINEs. The coexpression of dimeric and monomeric Alu RNA in several hybrids suggests a precursor-product relationship.

Multiple dispersed loci produce small cytoplasmic Alu RNA

Alu repeats are short interspersed elements (SINEs) of dimeric structure whose transposition sometimes leads to heritable disorders in humans. Human cells contain a poly(A)- small cytoplasmic transcript of -120 nucleotides (nt) homologous to the left Alu monomer. Although its monomeric size indicates that small cytoplasmic Alu (scAlu) RNA is not an intermediary of human Alu transpositions, a less abundant poly(A)-containing Alu transcript of dimeric size and specificity expected of a transposition intermediary is also detectable in HeLa cells (A. G. Matera, U. Hellmann, M. F. Hintz, and C. W. Schmid, Mol. Cell. Biol. 10:5424-5432, 1990). Although its function is unknown, the accumulation of Alu RNA and its ability to interact with a conserved protein suggest a role in cell biology (D.-Y. Chang and R. J. Maraia, J. Biol. Chem. 268:6423-28, 1993). The relationship between the -120- and -300-nt Alu transcripts had not been determined. However, a B1 SINE produces scB1 RNA by posttranscriptional processing, suggesting a similar pathway for scAlu. An Alu SINE which recently transposed into the neurofibromatosis 1 locus was expressed in microinjected frog oocytes. This neurofibromatosis 1 Alu produced a primary transcript followed by the appearance of the scAlu species. 3' processing of a synthetic -300-nt Alu RNA by HeLa nuclear extract in vitro also produced scAlu RNA. Primer extension of scAlu RNA indicates synthesis by RNA polymerase III. HeLa-derived scAlu cDNAs were cloned so as to preserve their 5'-terminal sequences and were found to correspond to polymerase III transcripts of the left monomeric components of three previously identified Alu SINE subfamilies. Rodent x human somatic cell hybrids express Alu RNAs whose size, heterogeneous length, and chromosomal distribution indicate their derivation from SINEs. The coexpression of dimeric and monomeric Alu RNA in several hybrids suggests a precursor-product relationship.

Activation of RNA polymerase III transcription of human Alu repetitive elements by adenovirus type 5: requirement for the E1b 58-kilodalton protein and the products of E4 open reading frames 3 and 6

We found that transcription of endogenous human Alu elements by RNA polymerase III was strongly stimulated following infection of HeLa cells with adenovirus type 5, leading to the accumulation of high levels of Alu transcripts initiated from Alu polymerase III promoters. In contrast to previously reported cases of adenovirus-induced activation of polymerase III transcription, induction required the E1b 58-kDa protein and the products of E4 open reading frames 3 and 6 in addition to the 289-residue E1a protein. In addition, E1a function was not required at high multiplicities of infection, suggesting that E1a plays an indirect role in Alu activation. These results suggest previously unsuspected regulatory properties of the adenovirus E1b and E4 gene products and provide a novel approach to the study of the biology of the most abundant class of dispersed repetitive DNA in the human genome.

Generalized Lévy-walk model for DNA nucleotide sequences

We propose a generalized Lévy walk to model fractal landscapes observed in noncoding DNA sequences. We find that this model provides a very close approximation to the empirical data and explains a number of statistical properties of genomic DNA sequences such as the distribution of strand-biased regions (those with an excess of one type of nucleotide) as well as local changes in the slope of the correlation exponent alpha. The generalized Lévy-walk model simultaneously accounts for the long-range correlations in noncoding DNA sequences and for the apparently paradoxical finding of long subregions of biased random walks (length lj) within these correlated sequences. In the generalized Lévy-walk model, the lj are chosen from a power-law distribution P(lj) varies as lj(-mu). The correlation exponent alpha is related to mu through alpha = 2-mu/2 if 2 < mu < 3. The model is consistent with the finding of "repetitive elements" of variable length interspersed within noncoding DNA.

Activation of RNA polymerase III transcription of human Alu repetitive elements by adenovirus type 5: requirement for the E1b 58-kilodalton protein and the products of E4 open reading frames 3 and 6

We found that transcription of endogenous human Alu elements by RNA polymerase III was strongly stimulated following infection of HeLa cells with adenovirus type 5, leading to the accumulation of high levels of Alu transcripts initiated from Alu polymerase III promoters. In contrast to previously reported cases of adenovirus-induced activation of polymerase III transcription, induction required the E1b 58-kDa protein and the products of E4 open reading frames 3 and 6 in addition to the 289-residue E1a protein. In addition, E1a function was not required at high multiplicities of infection, suggesting that E1a plays an indirect role in Alu activation. These results suggest previously unsuspected regulatory properties of the adenovirus E1b and E4 gene products and provide a novel approach to the study of the biology of the most abundant class of dispersed repetitive DNA in the human genome.

The use of polymorphic Alu insertions in human DNA fingerprinting

We have characterized several Human Specific (HS) Alu insertions as either dimorphic (TPA25, PV92, APO), slightly dimorphic (C2N4 and C4N4) or monomorphic (C3N1, C4N6, C4N2, C4N5, C4N8) based on studies of Caucasian, Asian, American Black and African Black populations. Our approach is based upon: 1) PCR amplification using primers complementary to the unique DNA sequences that flank the site of insertion of the different Alu elements studied; 2) gel electrophoresis and scoring according to the presence or absence of an Alu insertion in one or both homologous chromosomes; 3) allele frequencies determined by gene counting and compared to Hardy-Weinberg expectations. Our DNA fingerprinting procedure using PCR amplification of diallelic polymorphic (dimorphic) Human Specific Alu insertions, may be used as a tool for genetic mapping, to characterize populations, study human migrational patterns, and track the inheritance of human genetic disorders.

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)

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.

Fusion of a free left Alu monomer and a free right Alu monomer at the origin of the Alu family in the primate genomes

In the primate genome, a typical Alu element corresponds to a dimeric structure composed of two different but related monomeric sequences arranged in tandem. However, the analysis of primate sequences found in GenBank reveals the presence of free left and free right Alu elements. Here, we report the statistical study of those monomeric elements. We found that only a small fraction of them results from a deletion of a dimeric Alu sequence. The majority derives from the amplification of monomeric progenitor sequences and constitutes two families of monomeric elements: a family of free left Alu monomers that is composed of two subfamilies and a small family of free right Alu monomers. Both families predated the dimeric Alu elements, and a phylogenetic analysis strongly suggests that the first progenitor of the dimeric Alu family arose through the fusion of a free left monomer with a free right monomer.

Modular transposition and the dynamical structure of eukaryote regulatory evolution

This paper examines a model in which transposable elements provide a modular architecture for the cellular genome, complemented by cellular recombinational transformations, arising in turn as a dynamical consequence of this modular structure. It is proposed that the ecology of transposable elements in a given organism is a function of recombinational protocols of the evolving cellular genome. In mammals this is proposed to involve coordinated meiosis-phased activation of LINEs, SINEs and retrogenes complemented by endogenous retroviral transfer between cells.

Reconstruction and analysis of human Alu genes

The existing classification of human Alu sequences is revised and expanded using a novel methodology and a larger set of sequence data. Our study confirms that there are two major Alu subfamilies, Alu-J and Alu-S. The Alu-S subfamily consists of at least five distinct subfamilies referred to as Alu-Sx, Alu-Sq, Alu-Sp, Alu-Sc, and Alu-Sb. The Alu-Sp and Alu-Sq subfamilies have been revealed by this study. Alu subfamilies differ from one another in a number of positions called diagnostic. In this paper the diagnostic positions are defined in quantitative terms and are used to evaluate statistical significance of the observed subfamilies. Each Alu subfamily most likely represents pseudogenes retroposed from evolving functional source Alu genes. Evidence presented in this paper indicates that Alu-Sp and Alu-Sc pseudogenes were retroposed from different source genes, during overlapping periods of time, and at different rates. Our analysis also indicates that the previously identified Alu-type transcript BC200 comes from an active Alu gene that might have existed even before the origin of dimeric Alu sequences. The source genes for Alu pseudogene families are reconstructed. It is assumed that diagnostic differences between reconstructed source genes reflect mutations that have occurred in true source Alu genes under natural selection. Some of these mutations are compensatory and are used to reconstruct a common secondary structure of Alu RNAs transcribed from the source genes. The biological function of Alu RNA is discussed in the context of its homology to the elongation-arresting domain of 7SL RNA.(ABSTRACT TRUNCATED AT 250 WORDS)