Adaptive Amplification

ABSTRACT

Modern techniques are revealing that repetition of segments of the genome, called amplification or gene amplification, is very common. Amplification is found in all domains of life, and occurs under conditions where enhanced expression of the amplified genes is advantageous. Amplification extends the range of gene expression beyond that which is achieved by control systems. It also is reversible because it is unstable, breaking down by homologous recombination. Amplification is believed to be the driving force in the clustering of related functions, in that it allows them to be amplified together. Amplification provides the extra copies of genes that allow evolution of functions to occur while retaining the original function. Amplification can be induced in response to cellular stressors. In many cases, it has been shown that the genomic regions that are amplified include those genes that are appropriate to upregulate for a specific stressor. There is some evidence that amplification occurs as part of a broad, general stress response, suggesting that organisms have the capacity to induce structural changes in the genome. This then allows adaptation to the stressful conditions. The mechanisms by which amplification arises are now being studied at the molecular level, but much is still unknown about the mechanisms in all organisms. Recent advances in our understanding of amplification in bacteria suggests new interpretations of events leading to human copy number variation, as well as evolution in general.     

Gene duplication as a major force in evolution

Gene duplication is an important mechanism for acquiring new genes and creating genetic novelty in organisms. Many new gene functions have evolved through gene duplication and it has contributed tremendously to the evolution of developmental programmes in various organisms. Gene duplication can result from unequal crossing over, retroposition or chromosomal (or genome) duplication. Understanding the mechanisms that generate duplicate gene copies and the subsequent dynamics among gene duplicates is vital because these investigations shed light on localized and genomewide aspects of evolutionary forces shaping intra-specific and inter-specific genome contents, evolutionary relationships, and interactions. Based on whole-genome analysis of Arabidopsis thaliana, there is compelling evidence that angiosperms underwent two whole-genome duplication events early during their evolutionary history. Recent studies have shown that these events were crucial for creation of many important developmental and regulatory genes found in extant angiosperm genomes. Recent studies also provide strong indications that even yeast (Saccharomyces cerevisiae), with its compact genome, is in fact an ancient tetraploid. Gene duplication can provide new genetic material for mutation, drift and selection to act upon, the result of which is specialized or new gene functions. Without gene duplication the plasticity of a genome or species in adapting to changing environments would be severely limited. Whether a duplicate is retained depends upon its function, its mode of duplication, (i.e. whether it was duplicated during a whole-genome duplication event), the species in which it occurs, and its expression rate. The exaptation of preexisting secondary functions is an important feature in gene evolution, just as it is in morphological evolution.     

The origin of new genes: glimpses from the young and old

Genome data have revealed great variation in the numbers of genes in different organisms, which indicates that there is a fundamental process of genome evolution: the origin of new genes. However, there has been little opportunity to explore how genes with new functions originate and evolve. The study of ancient genes has highlighted the antiquity and general importance of some mechanisms of gene origination, and recent observations of young genes at early stages in their evolution have unveiled unexpected molecular and evolutionary processes.     

Preferential Duplication of Intermodular Hub Genes: An Evolutionary Signature in Eukaryotes Genome Networks

Whole genome protein-protein association networks are not random and their topological properties stem from genome evolution mechanisms. In fact, more connected, but less clustered proteins are related to genes that, in general, present more paralogs as compared to other genes, indicating frequent previous gene duplication episodes. On the other hand, genes related to conserved biological functions present few or no paralogs and yield proteins that are highly connected and clustered. These general network characteristics must have an evolutionary explanation. Considering data from STRING database, we present here experimental evidence that, more than not being scale free, protein degree distributions of organisms present an increased probability for high degree nodes. Furthermore, based on this experimental evidence, we propose a simulation model for genome evolution, where genes in a network are either acquired de novo using a preferential attachment rule, or duplicated with a probability that linearly grows with gene degree and decreases with its clustering coefficient. For the first time a model yields results that simultaneously describe different topological distributions. Also, this model correctly predicts that, to produce protein-protein association networks with number of links and number of nodes in the observed range for Eukaryotes, it is necessary 90% of gene duplication and 10% of de novo gene acquisition. This scenario implies a universal mechanism for genome evolution.     

Mechanisms of DNA sequence amplification and their evolutionary consequences

DNA sequence amplification is a phenomenon that occurs predictably at defined stages during normal development in some organisms and has been shown to occur spontaneously, but sporadically, in a variety of cells, including mammalian cells, selected for overproduction of a gene product. Developmentally programmed gene amplification includes rDNA amplification during o?genesis in amphibia, chorion protein gene amplification in Drosophila and the chromosomal changes accompanying macronuclear formation in ciliates. Selected gene amplification is illustrated by mutant mammalian cells which have been selected in vitro or in vivo for the overproduction of a gene product. In these cells the unit of DNA that is amplified is much larger than the gene under selection, and appears to be formed by multiple recombination events, which bring together sequences not normally adjacent to each other. Often the product of amplification can be seen microscopically as aberrant chromosome forms. The vast majority of DNA amplification events occur in somatic nuclei, and thus would not have any direct effect on the evolution of a genome. However, the ability to amplify DNA in somatic cells does have consequences for the composition of the genomes of the organisms in which it can occur, and should DNA amplification occur, even sporadically, in germ-line cells the potential effect on evolution would be great.     

Amplification of oncogenes in human cancer cells

Gene amplification refers to a genomic change that results in an increased dosage of the gene(s) affected. Amplification represents one of the major molecular pathways through which the oncogenic potential of proto-oncogenes is activated during tumorigenesis. The architecture of amplified genomic structures is simple in some tumor types, involving in the vast majority of cases only one gene, such as MYCN in neuroblastomas. On the other hand, it can be complex and discontinuous, involving several syntenic co-amplified genes, such as in the 11q13 amplification in breast cancer, although in many of these cases there may be a single target gene. The presence of different nonsyntenic amplified genes raises the possibility that cells of certain tumors are susceptible to independent amplification events. In general, the amplified genes do not undergo additional damage by mutations. The data indicate that it is the enhanced level of a wild-type protein that contributes to tumorigenesis. BioEssays 20 :473–479, 1998.© 1998 John Wiley & Sons, Inc.     

Global chromosomal structural instability in a subpopulation of starving Escherichia coli cells

Copy-number variations (CNVs) constitute very common differences between individual humans and possibly all genomes and may therefore be important fuel for evolution, yet how they form remains elusive. In starving Escherichia coli, gene amplification is induced by stress, controlled by the general stress response. Amplification has been detected only encompassing genes that confer a growth advantage when amplified. We studied the structure of stress-induced gene amplification in starving cells in the Lac assay in Escherichia coli by array comparative genomic hybridization (aCGH), with polymerase chain reaction (pcr) and DNA sequencing to establish the structures generated. About 10% of 300 amplified isolates carried other chromosomal structural change in addition to amplification. Most of these were inversions and duplications associated with the amplification event. This complexity supports a mechanism similar to that seen in human non-recurrent copy number variants. We interpret these complex events in terms of repeated template switching during DNA replication. Importantly, we found a significant occurrence (6 out of 300) of chromosomal structural changes that were apparently not involved in the amplification event. These secondary changes were absent from 240 samples derived from starved cells not carrying amplification, suggesting that amplification happens in a differentiated subpopulation of stressed cells licensed for global chromosomal structural change and genomic instability. These data imply that chromosomal structural changes occur in bursts or showers of instability that may have the potential to drive rapid evolution.     

On the mechanism of gene amplification induced under stress in Escherichia coli

Gene amplification is a collection of processes whereby a DNA segment is reiterated to multiple copies per genome. It is important in carcinogenesis and resistance to chemotherapeutic agents, and can underlie adaptive evolution via increased expression of an amplified gene, evolution of new gene functions, and genome evolution. Though first described in the model organism Escherichia coli in the early 1960s, only scant information on the mechanism(s) of amplification in this system has been obtained, and many models for mechanism(s) were possible. More recently, some gene amplifications in E. coli were shown to be stress-inducible and to confer a selective advantage to cells under stress (adaptive amplifications), potentially accelerating evolution specifically when cells are poorly adapted to their environment. We focus on stress-induced amplification in E. coli and report several findings that indicate a novel molecular mechanism, and we suggest that most amplifications might be stress-induced, not spontaneous. First, as often hypothesized, but not shown previously, certain proteins used for DNA double-strand-break repair and homologous recombination are required for amplification. Second, in contrast with previous models in which homologous recombination between repeated sequences caused duplications that lead to amplification, the amplified DNAs are present in situ as tandem, direct repeats of 7–32 kilobases bordered by only 4 to 15 base pairs of G-rich homology, indicating an initial non-homologous recombination event. Sequences at the rearrangement junctions suggest nonhomologous recombination mechanisms that occur via template switching during DNA replication, but unlike previously described template switching events, these must occur over long distances. Third, we provide evidence that 3′-single-strand DNA ends are intermediates in the process, supporting a template-switching mechanism. Fourth, we provide evidence that lagging-strand templates are involved. Finally, we propose a novel, long-distance template-switching model for the mechanism of adaptive amplification that suggests how stress induces the amplifications. We outline its possible applicability to amplification in humans and other organisms and circumstances.     

Identification and cloning of a novel amplified DNA sequence in human malignant fibrous histiocytoma derived from a region of chromosome 12 frequently rearranged in soft tissue tumors.

Amplification of cellular oncogenes occurs frequently in several human cancers and is an important mechanism of increased gene expression. Identification of amplified genes in tumor cells has proved to be a useful approach for understanding genetic alterations in cancer. Previous procedures for isolating probes from amplified DNA sequences have relied on tissue culture cells, limiting the range of tumors that can be studied and raising questions of in vitro artifact. We have circumvented these problems by combining in gel renaturation of amplified sequences with the polymerase chain reaction. Using this approach, we have identified and partially cloned a DNA amplification unit from biopsies of human malignant fibrous histiocytoma. This amplification unit is derived from chromosome 12q13-14, a site commonly involved in rearrangements in soft tissue tumors, and contains at least one transcribed region (designated SAS, for sarcoma amplified sequence).     

The amplification and evolution of orthologous 22-kDa α-prolamin tandemly arrayed genes in <Emphasis Type="Italic">coix</Emphasis>, sorghum and maize genomes

Tandemly arrayed genes (TAGs) account for about one-third of the duplicated genes in eukaryotic genomes. They provide raw genetic material for biological evolution, and play important roles in genome evolution. The 22-kDa prolamin genes in cereal genomes represent typical TAG organization, and provide the good material to investigate gene amplification of TAGs in closely related grass genomes. Here, we isolated and sequenced the Coix 22-kDa prolamin (coixin) gene cluster (283 kb), and carried out a comparative analysis with orthologous 22-kDa prolamin gene clusters from maize and sorghum. The 22-kDa prolamin gene clusters descended from orthologous ancestor genes, but underwent independent gene amplification paths after the separation of these species, therefore varied dramatically in sequence and organization. Our analysis indicated that the gene amplification model of 22-kDa prolamin gene clusters can be divided into three major stages. In the first stage, rare gene duplications occurred from the ancestor gene copy accidentally. In the second stage, rounds of gene amplification occurred by unequal crossing over to form tandem gene array(s). In the third stage, gene array was further diverged by other genomic activities, such as transposon insertions, segmental rearrangements, etc. Unlike their highly conserved sequences, the amplified 22-kDa prolamin genes diverged rapidly at their expression capacities and expression levels. Such processes had no apparent correlation to age or order of amplified genes within TAG cluster, suggesting a fast evolving nature of TAGs after gene amplification. These results provided insights into the amplification and evolution of TAG families in grasses.     

DNA sequence of a 3.8 kilobase pair region controlling Drosophila chorion gene amplification

During Drosophila oogenesis, two clusters of chorion genes and their flanking DNA sequences undergo amplification in the ovarian follicle cells. Amplification results from repeated rounds of initiation and bidirectional replication within the chorion gene regions, possibly from a single origin, producing nested replication forks. Previously we have shown that following reintroduction into the Drosophila genome, a specific 3.8 kilobase pair DNA segment from the amplified third chromosome domain could induce developmentally regulated amplification at its site of insertion. Here we present the complete nucleotide sequence of this amplification control element and of genes encoding the chorion structural proteins s18-1 and s15-1, which are contained within it. Sequences that may be involved in the regulation of chorion gene amplification and expression are identified.     

Gene duplication,transfer, and evolution in the chloroplast genome

In addition to the nuclear genome, organisms have organelle genomes. Most of the DNA present in eukaryotic organisms is located in the cell nucleus. Chloroplasts have independent genomes which are inherited from the mother. Duplicated genes are common in the genomes of all organisms. It is believed that gene duplication is the most important step for the origin of genetic variation, leading to the creation of new genes and new gene functions. Despite the fact that extensive gene duplications are rare among the chloroplast genome, gene duplication in the chloroplast genome is an essential source of new genetic functions and a mechanism of neo-evolution. The events of gene transfer between the chloroplast genome and nuclear genome via duplication and subsequent recombination are important processes in evolution. The duplicated gene or genome in the nucleus has been the subject of several recent reviews. In this review, we will briefly summarize gene duplication and evolution in the chloroplast genome. Also, we will provide an overview of gene transfer events between chloroplast and nuclear genomes.     

Rapid and asymmetric divergence of duplicate genes in the human gene coexpression network

Background  

While gene duplication is known to be one of the most common mechanisms of genome evolution, the fates of genes after duplication are still being debated. In particular, it is presently unknown whether most duplicate genes preserve (or subdivide) the functions of the parental gene or acquire new functions. One aspect of gene function, that is the expression profile in gene coexpression network, has been largely unexplored for duplicate genes.     

Genome-wide selection for increased copy number in Acinetobacter baylyi ADP1: locus and context-dependent variation in gene amplification

Renewed interest in gene amplification stems from its importance in evolution and a variety of medical problems ranging from drug resistance to cancer. However, amplified DNA segments (amplicons) are not fully characterized in any organism. Here we report a novel Acinetobacter baylyi system for genome‐wide studies. Amplification mutants that consume aromatic compounds were selected under conditions requiring high‐level expression from three promoters in a linked set of chromosomal genes. Tools were developed to relocate these catabolic genes to any non‐essential chromosomal position, and 49 amplification mutants from five genomic contexts were characterized. Amplicon size (18–271 kb) and copy number (2–105) indicated that 30% of mutants carried more than 1 Mb of amplified DNA. Amplification features depended on genomic position. For example, amplicons from one locus were similarly sized but displayed variable copy number, whereas those from another locus were differently sized but had comparable copy number. Additionally, the importance of sequence context was highlighted in one region where amplicons differed depending on the presence of a promoter mutation in the strain from which they were selected. DNA sequences at amplicon boundaries in 19 mutants reflected illegitimate recombination. Furthermore, steady‐state duplication frequencies measured under non‐selective conditions (10^?4 to 10^?5) confirmed that spontaneous gene duplication is a major source of genetic variation.     

Gene Conversion Drives Within Genic Sequences: Concerted Evolution of Ribosomal RNA Genes in Bacteria and Archaea

Multiple copies of a given ribosomal RNA gene family undergo concerted evolution such that sequences of all gene copies are virtually identical within a species although they diverge normally between species. In eukaryotes, gene conversion and unequal crossing over are the proposed mechanisms for concerted evolution of tandemly repeated sequences, whereas dispersed genes are homogenized by gene conversion. However, the homogenization mechanisms for multiple-copy, normally dispersed, prokaryotic rRNA genes are not well understood. Here we compared the sequences of multiple paralogous rRNA genes within a genome in 12 prokaryotic organisms that have multiple copies of the rRNA genes. Within a genome, putative sequence conversion tracts were found throughout the entire length of each individual rRNA genes and their immediate flanks. Individual conversion events convert only a short sequence tract, and the conversion partners can be any paralogous genes within the genome. Interestingly, the genic sequences undergo much slower divergence than their flanking sequences. Moreover, genomic context and operon organization do not affect rRNA gene homogenization. Thus, gene conversion underlies concerted evolution of bacterial rRNA genes, which normally occurs within genic sequences, and homogenization of flanking regions may result from co-conversion with the genic sequence. Received: 31 March 2000 / Accepted: 15 June 2000     

Adaptive molecular evolution of HINTW,a female-specific gene in birds

It is well established that many genes on the male-specific Y chromosome of organisms such as mammals are involved in male reproduction and may evolve rapidly because of positive selection on male reproductive traits. In contrast, very little is known about the function and evolution of W-linked genes restricted to the female genome of organisms with female heterogamety. For birds (males ZZ, females ZW), only one W-linked gene (HINTW) is sufficiently different from its Z-linked homolog to indicate a female-specific function. Here, we report that HINTW shows evidence of adaptive molecular evolution, implying strong positive selection for new functional properties in female birds. Moreover, because HINTW is expressed in the gonads of female birds just before sexual differentiation and is thus a candidate for sex determination, it suggests adaptive evolution related to female development. This provides the first example of Darwinian evolution of a gene restricted to the female genome of any organism. Given that HINTW exists in multiple copies on W, similar to some testis-specific genes amplified on mammalian Y, avian HINTW may thus potentially represent a female parallel to the organization and evolution of Y chromosome genes involved in male reproduction and development.     

Evolutionary origins of human apoptosis and genome-stability gene networks

Apoptosis is essential for complex multicellular organisms and its failure is associated with genome instability and cancer. Interactions between apoptosis and genome-maintenance mechanisms have been extensively documented and include transactivation-independent and -dependent functions, in which the tumor-suppressor protein p53 works as a ‘molecular node’ in the DNA-damage response. Although apoptosis and genome stability have been identified as ancient pathways in eukaryote phylogeny, the biological evolution underlying the emergence of an integrated system remains largely unknown. Here, using computational methods, we reconstruct the evolutionary scenario that linked apoptosis with genome stability pathways in a functional human gene/protein association network. We found that the entanglement of DNA repair, chromosome stability and apoptosis gene networks appears with the caspase gene family and the antiapoptotic gene BCL2. Also, several critical nodes that entangle apoptosis and genome stability are cancer genes (e.g. ATM, BRCA1, BRCA2, MLH1, MSH2, MSH6 and TP53), although their orthologs have arisen in different points of evolution. Our results demonstrate how genome stability and apoptosis were co-opted during evolution recruiting genes that merge both systems. We also provide several examples to exploit this evolutionary platform, where we have judiciously extended information on gene essentiality inferred from model organisms to human.     

Characterization of the MCT-1 pseudogene: identification and implication of its location in a highly amplified region of chromosome 20

The MCT-1 oncogene was initially identified as an amplified gene on chromosome Xq22-24 in a T-cell lymphoma. MCT-1 is over-expressed in a subset of diffuse large B-cell lymphoma (DLBCL), a common form of Non-Hodgkin's Lymphoma (NHL). We have identified a pseudogene for MCT-1 (PsiMCT-1) that is located on chromosome 20q11.2, a region within an amplicon containing several important genes frequently amplified in certain breast and ovarian cancers. Genomic analysis revealed that PsiMCT-1 is a processed pseudogene. Interestingly, both MCT-1 and its pseudogene are located on regions of the genome that are frequently amplified in several different human malignancies. MCT-1 is the oldest known oncogene and its insertion as a pseudogene occurred at a later time point in evolution. Existence of PsiMCT-1 should be considered when analyzing genomic amplification and or expression of MCT-1. Analysis of MCT-1 and PsiMCT-1 might provide clues to cancer genes and their evolution across species.     

Intrastrand annealing leads to the formation of a large DNA palindrome and determines the boundaries of genomic amplification in human cancer

Amplification of large chromosomal regions (gene amplification) is a common somatic alteration in human cancer cells and often is associated with advanced disease. A critical event initiating gene amplification is a DNA double-strand break (DSB), which is immediately followed by the formation of a large DNA palindrome. Large DNA palindromes are frequent and nonrandomly distributed in the genomes of cancer cells and facilitate a further increase in copy number. Although the importance of the formation of large DNA palindromes as a very early event in gene amplification is widely recognized, it is not known how a DSB is resolved to form a large DNA palindrome and whether any local DNA structure determines the location of large DNA palindromes. We show here that intrastrand annealing following a DNA double-strand break leads to the formation of large DNA palindromes and that DNA inverted repeats in the genome determine the efficiency of this event. Furthermore, in human Colo320DM cancer cells, a DNA inverted repeat in the genome marks the border between amplified and nonamplified DNA. Therefore, an early step of gene amplification is a regulated process that is facilitated by DNA inverted repeats in the genome.