Introduction

Operons (clusters of co-regulated genes with related functions) are a well-known feature of prokaryotic genomes. Archeal and bacterial genomes generally contain a small number of highly conserved operons and a much larger number of unique or rare ones [1]. Functional gene clustering also occurs in eukaryotes, from yeasts to filamentous fungi, mammals, nematodes, and plants [2]. The members of these eukaryotic gene clusters contribute to a common function but do not usually share sequence similarity. These gene clusters therefore represent functional gene organizations with operon-like features (physical clustering and co-regulation), although the genes are not usually transcribed as a single mRNA as is the case in prokaryotes. This article reviews facets of genome organization in prokaryotes and eukaryotes that are of relevance for understanding the significance of the establishment, maintenance, and dissipation of functional gene clusters and the evolutionary forces that shape genome architecture.

Classical operons

The term “operon” was coined by Jacob and Monod [35], who characterized the first defined classical operon, the lac operon, in Escherichia coli. The lac operon consists of three structural genes that are required for lactose utilisation, lacZ, lacY, and lacA (Fig. 1). These genes encode a β-galactosidase, a lac permease, and a transacetylase, respectively. The first step in lactose metabolism is catalyzed by β-galactosidase, which cleaves lactose into galactose and glucose. Lactose is then taken up by the transmembrane protein, lac permease. The transacetylase transfers an acetyl group from coenzyme A (CoA) to the hydroxyl group of the galactosides. The regulatory gene lacI encodes the lac repressor, which in its active form inhibits the transcription of the structural genes by binding an operator. The lacZYA genes are co-ordinately regulated, and expression is induced by lactose under conditions of carbon starvation. Regulation is mediated by co-transcription, the lacZYA genes being transcribed in a single mRNA. Numerous examples of bacterial operons have since been described [68]. Operons usually code for genes in the same functional pathway. However, there are also examples of operons that contain genes with no obvious functional relationship. Genes within operons of this kind may be required under the same environmental conditions despite being involved in different pathways [9].

Fig. 1
figure 1

The Escherichia coli lac regulon. lacI encodes the lac repressor, which in its active form inhibits the transcription of the structural genes by binding an operator. The genes within the lac operon (lacZYA) are transcribed as a single mRNA. Expression is induced by lactose under conditions of carbon starvation. Expression of lacZYA is positively regulated by an activator whose production is controlled by the concentration of extracellular glucose

Although the lacI repressor gene is able to regulate expression of the lacZYA genes when placed anywhere in the chromosome, this gene is normally positioned immediately upstream of lacZYA. Co-localization of the regulatory gene with the genes that it regulates has been suggested to be a “selfish” property of the lac gene cluster, since such organization may increase the fitness of this group of genes by allowing horizontal as well as vertical inheritance [10, 11]. Operons are certainly known to undergo horizontal gene transfer (HGT) [10, 12, 13]. However, essential genes are commonly found in operons, as are other genes that are not known to be transmitted by HGT, providing evidence against the selfish operon theory [14, 15]. The selfish cluster theory also does not explain the many operons that contain functionally unrelated genes [9]. The emergence of new operons will require not only the coming together of genes but also the establishment and maintenance of co-ordinate regulation of these genes. A more likely explanation for the existence of operons is concerned with regulation.

The regulatory model provides several potential explanations for the existence of operons [15]. It has been argued that co-regulation could be evolved more easily by modifying two independent promoters than by placing two genes in proximity [10]. A counter-argument to this is that, for complex regulation, an operon with one complex promoter might be expected to arise more readily than would two independent complex promoters [12]. The dependence of several genes on a single regulatory sequence is expected to put this sequence under stronger selection, so allowing for the emergence of more complex regulatory strategies [15]. The observation that operons do tend to have more complex conserved regulatory sequences than individually transcribed genes is consistent with this hypothesis [9, 12, 16]. Genes within new operons are significantly less likely to be optimally spaced when compared to old operons, which is consistent with the idea that canonical spacings form by deletion after the operon has already formed [9]. In laboratory experiments, the expression level of the lac operon evolves to optimality in a few hundred generations [17]. Thus, changes in operon spacing could reflect fine tuning of expression levels.

Transcription of genes in a single transcript is expected to diminish gene expression noise and ensure more precise stoichiometry [15]. The most highly conserved operons do tend to code for components of protein complexes [9, 14, 18, 19]. However, there are many examples of operons that do not code for protein complexes [9]. In addition, only a few percent of known protein–protein interactions involve genes encoded by the same operon [20]. Furthermore, the optimal expression level of each gene is not the same for all genes in an operon [15].

Rapid and reliable gene regulation may require the transcription factor gene to be in close proximity to the sites within the genome to which it binds (the rapid search hypothesis [224]). In prokaryotes, transcription and translation are coupled spatially and temporally. Such organization would therefore provide for synthesis of transcription factors near the genes that they regulate, enabling rapid binding of co-localized sites and tight co-ordinate regulation. Computer simulations have been used to address the relationship between genome organization and biophysical constraints and have provided evidence to support the rapid search hypothesis [21]. Transcription–translational coupling may also facilitate co-ordinate downstream processes such as assembly of protein complexes through co-translational folding [25], and cell compartmentalization [26].

The birth and death of operons is a dynamic process. The complete genome sequences of over 1,000 prokaryotes have now been determined. This wealth of sequence information has enabled genome-wide studies of bacterial genomes to be carried out, and the evolutionary life-cycle of operons to be inferred by comparison of related bacterial species [9]. HGT represents one source of operons, and is the primary origin of these functional gene clusters as predicted by the selfish operon model [15]. In this case, the genes within the operon have homology with genes from other sequenced organisms and can readily be identified as the products of a HGT event. In addition, new operons are highly enriched for “ORFan” genes—genes that lack identifiable homologues outside a group of related bacteria. Most ORFans are functional protein-encoding genes that contribute to the fitness of the organism (i.e., are under purifying selection) and were probably acquired from bacteriophage [27]. Such ORFan genes tend to be located 3′ of native genes in operons (Fig. 2). This arrangement may be selected for because the ORFan gene is transcribed from a native promoter without perturbing the expression of the native gene. The grouping of more than one ORFan gene in an operon may indicate that the ORFan genes have been introduced by HGT from a source that has not yet been sequenced. Finally, operons consisting of native genes can form without HGT. These new operons can arise as a consequence of rearrangements that bring more distant genes into proximity, or by deletion of intervening genes (Fig. 2).

Fig. 2
figure 2

Mechanisms of operon formation in bacteria (adapted from Ref. [9]). ORFans are genes that lack identifiable homologues outside a group of closely related bacteria. Most ORFans are functional protein-encoding genes that are under purifying selection and so are likely to contribute to the fitness of the organism. They were probably acquired from bacteriophage

Because few operons are conserved across all or even most bacteria, it is clear that after operons form many of them “die”. Operons could be lost by the deletion of one/more genes or alternatively by splitting the operon apart. Since operon formation often brings functionally related genes together, it seems unlikely to be a neutral process. If operon formation is driven by gene expression, then it should be associated with changes in the expression patterns of the constituent genes. Studies of the expression patterns of genes in E. coli operons and of orthologous genes in “not-yet” operons in the related bacterium Shewanella oneidensis MR-1 have provided compelling evidence that operon formation has a major effect on gene expression patterns [9]. Similarly, “dead” operons are significantly less co-expressed than live operons but significantly more co-expressed than random pairs of genes. Thus, operon destruction also has a major effect on gene expression patterns, but it does not entirely eliminate the similarity of expression. The turnover of operon structure may accompany switching between constitutive and inducible expression. Although constitutive expression may seem wasteful and hence deleterious, favorable gene combinations cannot be selected for unless the genes are expressed. Constitutive gene expression, even at very low levels, would logically be expected to be necessary to enable the selection-mediated garnering of beneficial combination of genes into operons with subsequent fine tuning of expression. While genes within the same operon are under much stronger selection to remain together than genes that are in different operons [28, 29], there is also evidence of weaker selection for high level interactions between operons, some of which are so widely conserved that they are known as super- or uberoperons [21, 30].

Secondary metabolism in filamentous fungi

Filamentous fungi produce a huge array of secondary metabolites (sometimes also referred to as natural products). These compounds are commonly synthesized by groups of genes that form metabolic gene clusters [3234]. The genes within these clusters are physically linked and co-regulated, but unlike bacterial operons they are not transcribed as a single mRNA. Nevertheless, these fungal gene clusters represent functional gene organizations with operon-like features (physical clustering and co-regulation). Examples include gene clusters for important pharmaceuticals (such as the β-lactam antibiotics, penicillin, and cephalosporin), the anti-hypercholesterolaemic agent lovastatin, ergopeptines, and carcinogenic toxins (aflatoxin and sterigmatocystin). Secondary metabolites are also important in mediating interactions between fungal pathogens and their hosts. For example, an unknown metabolite synthesized by the ACE1 gene cluster in the rice blast fungus Magnaporthe grisea is involved in recognition of particular rice cultivars [35, 36], and the host selective HC-toxin produced by the corn pathogen Cochliobolus carbonum is critical for ability to cause disease on cultivars that have the Hm resistance gene [3739]. Such gene clusters generally involve “signature” secondary metabolic genes such as non-ribosomal peptide synthases (NRPS), type I polyketide synthases (PKS), terpene cyclases (TS), and dimethylallyl tryptophan synthetases (DMATS) genes, for the synthesis of non-ribosomal peptides, polyketides, terpenes, and indole alkaloids, respectively [32]. These signature genes are clustered along with various combinations of genes for further metabolite elaboration (e.g., oxidoreductases, methylases, acetylases, esterases), transporters, and sometimes (but not always) regulators [32, 33, 40]. While the first fungal gene clusters were identified using a combination of genetic, molecular genetic and biochemical approaches, the advent of fungal genome sequencing has enabled facile discovery of new candidate secondary metabolic gene clusters based on genome browsing and co-expression analysis [3234, 40].

Many fungal secondary metabolites have important biological properties such as antibacterial, antifungal, or antitumor activity [41]. The exploitation of fungal metabolites for pharmaceutical purposes was pioneered by the discovery of penicillin in 1929 and its subsequent development for large-scale use as an antibiotic during the Second World War. The fungal natural product repertoire has since been the subject of extensive screening programmes for drug discovery [32]. Although some secondary metabolites have been shown to be important in mediating interactions between fungal pathogens and their hosts [33, 36, 37, 42, 43], in many cases the biological significance of these compounds for the producing fungus is unknown. The production of different types of compound is often restricted to particular fungal lineages, and the most likely function of these compounds is in niche adaptation and survival. Many filamentous fungi live saprophytically in the soil where they are exposed to a diverse range of organisms. Secondary metabolites may therefore act as mediators of interactions within soil communities. Secondary metabolite production has recently been shown to protect Aspergillus nidulans from predation by an arthropod [44]. In a more complex three-way interaction, colonization of perennial ryegrass by secondary metabolite-producing fungal endophytes has been shown to confer protection against insect herbivory [45].

Secondary metabolite gene clusters in filamentous fungi commonly contain a gene for a pathway-specific transcription factor that positively regulates expression of the associated biosynthetic genes, each of which has its own promoter. These transcription factors are often Zn(II)2Cys6 zinc binuclear cluster proteins, a class of protein so far found only in fungi [32]. One such example is AflR, which is required for aflatoxin and sterigmatocystin biosynthesis in Aspergilli [46, 47]. Other transcription factors that are encoded in biosynthetic gene clusters include Cys2 His2 zinc-finger proteins (Tri6 and MRT16 for trichothecene production) [48] and an ankyrin repeat protein (ToxE for HC-toxin production) [38]. Transcription factor genes for synthesis of ergovaline and lolitrem in the endophytic fungi Neotyphodium lolii and Epichloe festuca do not reside within the cognate biosynthetic gene clusters and are as yet unidentified [4952]. In these latter cases, identification of pathway regulators will necessarily rely on forward screens for mutants with altered regulation of expression of the pathway, on reverse approaches that involve searching for regulatory proteins that bind to promoters of characterized biosynthetic genes, and/or on genome-wide co-expression analysis.

The Aspergillus laeA gene encodes a nuclear protein with homology to arginine and histone methyltransferases [32, 5357]. LaeA was identified in a screen for mutants of A. nidulans that were affected in their ability to synthesize sterigmatocystin [53]. Deletion of laeA results in loss of aflR gene expression and sterigmatocystin and aflatoxin synthesis in A. nidulans and A. flavus. It transpires that laeE deletion and overexpression strains are also affected in the synthesis of several other characterized and novel Aspergillus secondary metabolites, indicating a role for LaeA as a global regulator of secondary metabolism [53, 57, 58]. Comparison of global gene expression in A. flavus wild-type, laeA mutant, and complemented strains has revealed that LaeA controls transcription of around 10% of the genes in the A. fumigatus genome. Many of these genes are in 13 of the 22 secondary metabolite clusters. Seven of the LaeA-regulated clusters are in subtelomeric regions of chromosomes with a high degree of heterochromatin [58]. Collectively, these data suggest that LaeA acts as a master regulator of secondary metabolism in Aspergillus through chromatin remodeling [53, 54]. This hypothesis is supported by chromatin immunoprecipitation (ChIP) studies. Heterochromatin mutants with enhanced sterigmatocystin biosynthesis show decreased trimethylation of lysine residue K9 of histone H3, whilst laeA mutants show increased trimethylation of this lysine residue and a concomitant decrease in sterigmatocystin production [33]. Deletion of the histone deacetylase (HdaA) gene results in early and increased expression of biosynthetic genes not only for sterigmatocystin but also for another secondary metabolic gene cluster for penicillin synthesis [59]. Treatment of Aspergillus species and other fungi with selective drugs that inhibit histone deacetylase or DNA methyltransferase gives altered secondary metabolite profiles compared to control treatments [5961]. It thus appears that epigenetic processes have important functions in the regulation of secondary metabolic gene clusters. Chemical genetic techniques are now being exploited along with genetic and genomics-based approaches to identify new cryptic pathways and metabolites in diverse filamentous fungi [55, 58, 60, 61]. Overexpression of transcription factors implicated in regulation of secondary metabolic pathways offers a further route to identification of new pathways and their end-products [55, 62]. Synthesis of secondary metabolites by filamentous fungi is also under environmental and developmental control. The signaling cascades associated with these tiers of regulation are integrated into the hierarchical regulation of expression of the gene clusters [32, 33, 63] (Fig. 3). LaeA has also recently been shown to control penicillin biosynthesis, pigmentation, and sporulation in Penicillium chrysogenum [64].

Fig. 3
figure 3

Different levels of regulation of the aflatoxin gene cluster in the fungus, Aspergillus nidulans. The genes for aflatoxin biosynthesis are clustered in a 70-kb region and encode at least 23 co-regulated transcripts (not all cluster genes are shown in this diagram). The positive regulatory gene aflR lies within the gene cluster and is required for the transcriptional activation of most, if not all, pathway genes. aflR also regulates three genes outside the aflatoxin gene cluster. LaeA is a master regulator of secondary metabolism in the Aspergilli and is required for AlfR-mediated expression of the aflatoxin biosynthetic cluster. LaeA also controls transcription of gene clusters for other secondary metabolites and is believed to act via chromatin remodeling. Histone deacetylase (HdaA) performs an opposing role to LaeA and functions to repress gene expression in this region. Synthesis of secondary metabolites in the Aspergilli is linked to environmental stimuli and development. In the light asexual development (sporulation) is induced and genes involved in aflatoxin are not expressed. Darkness induces sexual development with associated induction of metabolite production, mediated by the proteins VelB and VeA. Adapted from [33]

There is evidence to suggest HGT of the penicillin gene cluster from bacteria to fungi [6567]. HGT of clusters between fungi may in part explain the discontinuous distribution of gene clusters for synthesis of secondary metabolites within the Ascomycetes [68, 69]. The selfish cluster hypothesis has been put forward to explain clustering of functionally related genes in fungi [66]. However, fungal genomes are very plastic, and it is likely that the formation and maintenance of metabolic gene clusters in fungal genomes is driven by selection for optimized production of metabolites that fulfil an adaptive function. Many fungal metabolic gene clusters are located close to telomeres, a chromosomal location that would be expected to facilitate recombination, DNA inversions, partial deletions, translocations, and other genomic rearrangements [7073]. Intragenic reorganization followed by vertical descent is therefore a more satisfactory explanation. Clustering may facilitate co-regulation of gene expression, although it is clearly not a prerequisite for this since expression of unlinked genes for other metabolic pathways can be readily co-regulated. As the number of complete genome sequences of filamentous fungi increases, it should become possible to elucidate and perhaps model the mechanisms that drive cluster formation and maintenance, following approaches similar to those used to study the life and death of bacterial operons. While this section has focused on gene clusters for the synthesis of secondary metabolites in filamentous fungi, it is noteworthy that clusters of diverse virulence genes with no obvious function in metabolism have recently been identified in the corn smut fungus Ustilago maydis following completion of the full genome sequence of this organism [74].

Metabolic gene clusters in yeast

Baker’s yeast Saccharomyces cerevisiae, unlike filamentous fungi, does not produce arrays of diverse secondary metabolites. Clusters of genes of related function are relatively unusual in S. cerevisiae by comparison with filamentous fungi, presumably for this reason. However, the S. cerevisiae genome does contain several functional gene clusters that are required for growth under certain conditions. These include gene clusters for utilization of specific carbon sources [e.g., the galactose (GAL) gene cluster], the DAL gene cluster for use of allantoin as a nitrogen source, and gene clusters for biotin synthesis, vitamin B1/B6 metabolism, and for arsenic resistance [7577]. Studies of the distribution, origin, and fate of these gene clusters have provided important insights into the mechanisms underpinning adaptation of yeasts to new ecological niches.

The DAL gene cluster of S. cerevisiae consists of six contiguous genes located close to a telomere [76, 78]. These genes enable yeast to use allantoin (a purine degradation product) as a nitrogen source (Fig. 4). The DAL gene cluster is completely conserved in the four closest relatives of S. cerevisiae. In less closely related species, the six genes are also clustered, but there are differences in the internal arrangement of gene order and the cluster is located in a different part of the genome (although probably still subtelomeric). The DAL cluster is not present in the genomes of more distantly related hemiascomycetes. However, homologues of the six DAL genes are found scattered around the genomes of these species. The species that possess a DAL cluster form a monophyletic group. Comparative analysis of the DAL genes and clusters in the genomes of different yeast species in combination with phylogenetic information has provided compelling evidence to suggest that the DAL cluster was assembled quite recently in evolutionary terms, after the split of the sensu stricto group of yeasts from other yeasts and hemiascomycetes [76]. Six of the eight genes involved in allantoin degradation, which were previously scattered around the genome, became relocated to a single subtelomeric site in an ancestor of S. cerevisiae and S. castelli. Four of these genes (DAL1, DAL2, DAL3, and DCG1) are single-copy genes in S. cerevisiae and seem to have transposed to their new locations in the cluster. This could have occurred by gene duplication followed by loss of the gene at the original locus. The other two genes, DAL4 and DAL7, were generated by duplication of progenitor genes that remain at their original sites in the S. cerevisiae genome (Fig. 5). These genomic rearrangements coincided with a biochemical reorganization of the purine degradation pathway, which switched to importing allantoin instead of urate. This change circumvented the need for urate oxidase, one of several oxygen-consuming enzymes lost by yeasts that can grow vigorously in anaerobic conditions (Fig. 4). It has therefore been proposed that selection for reduced dependence on oxygen led to a switch from urate to allantoin utilization in an ancestor of the sensu stricto group of yeasts [76]. Natural sources of allantoin for yeasts are plants [79] and insect excretion [80].

Fig. 4
figure 4

The allantoin degradation pathway—an adaptation to growth under oxygen-limiting conditions in Saccharomyces cerevisiae. In the classical purine degradation pathway, xanthine is converted to urate and then to allantoin, in two successive oxidation steps catalyzed by the peroxisomal enzymes xanthine dehydrogenase (XDH) and urate oxidase (UOX). XDH genes are present in filamentous fungi but not in yeasts. To use purine derivatives as a nitrogen source yeasts must therefore import urate, allantoin or allantoate from outside the cell. Yeasts that lack the DAL cluster (e.g., Kluyveromyces lactis, Saccharomyces kluyveri, and Zygosaccharomyces rouxii) are all able to grow on urate as a sole nitrogen source, presumably using urate permease (UAP) to import it, UOX to oxidize it and the DAL pathway enzymes to break it down to urea. In contrast, S. cerevisiae and Saccharomyces castelli have lost the ability to use urate, have no UOX or UAP genes, and instead import allantoin. The allantoin permease gene DAL4 is a duplicate of the uracil permease gene FUR4. The Dal4 and Fur4 proteins are members of a purine-related transporter family. The subsequent degradation steps involve the same DAL pathway genes in all yeasts, but in S. cerevisiae and S. castelli the genes have been organized into a cluster and the malate synthase gene MLS1 has been duplicated to produce DAL7. MLS1 and DAL7 both encode malate synthase but they are regulated differently. The glyoxylate cycle gene MLS1 is glucose repressed, whereas DAL7 is nitrogen-repressed. The reaction catalyzed by UOX requires molecular oxygen as a substrate and takes place in the peroxisome. Biochemical reorganization of the purine degradation pathway to enable import of allantoin instead of urate eliminates the oxygen-requiring step mediated by UOX and coincided with the formation of the DAL gene cluster. This biochemical reorganization may have been driven by selection for ability to grow under conditions of oxygen limitation. Reproduced from [76]

Fig. 5
figure 5

The birth of the DAL gene cluster. The DAL gene cluster on S. cerevisiae chromosome IX (red) lies within a sister region between chromosomes IX and XI (genes shown in pale yellow). The corresponding region in K. waltii, a yeast species that does not contain the DAL gene cluster, contains a merge from these two chromosomes (genes shown at the bottom in pale blue). The K. waltii orthologues of the six DAL genes are scattered around the genome (upper left). DAL1, DAL2, DAL3, and DCG1 apparently transposed to the cluster site, while DAL4 and DAL7 were formed by duplication of FUR4 and MLS1. The region of the K. waltii corresponding to the site into which the DAL cluster has inserted is indicated with a red circle. Adapted from [76]

The selection for formation of new metabolic gene clusters such as the DAL gene cluster is likely to be intense, driven by the need to adapt to growth under different environmental conditions. Gene clusters that have been formed by epistatic selection are expected to be recombination cold spots and so to be in linkage disequilibrium [81], and this is indeed the case for the DAL gene cluster [76]. Epistatic selection for linkage may in addition be driven by the need to select for combinations of alleles that interact well in order to avoid the accumulation of toxic pathway intermediates within cells. For example, glyoxylate, which is an intermediate in the DAL pathway (Fig. 4), is toxic to yeast [78]. Glyoxylate is produced by the Dal3 reaction and removed by the Dal7 reaction. There may therefore be selection for alleles of DAL3 and DAL7 that interact well and facilitate metabolic channeling. The finding that Dal3 enzyme activity is reduced in a dal7 mutant is consistent with this channeling hypothesis [76, 82].

The DAL gene cluster is subtelomeric and lies in an Htz1-activated domain (HZAD) of the S. cerevisiae genome. HZADs are regions of the genome that are decorated with the histone H2A variant H2A.Z (Htz1) rather than with the normal histone H2A [83]. Htz1 preferentially associates with narrow regions within the promoters of genes that are normally maintained in repressed form but are strongly induced under specific growth conditions or during particular gene expression programmes. A model has been proposed in which Hzt1 associates to specific nucleosomes in the promoters of inactive genes in order to poise, and perhaps organize, chromatin structure in a manner that is permissive to transcription initiation [84]. The genes in the DAL cluster are negatively regulated by the Hst-Sum1 system, which represses expression of mid-sporulation genes during mitotic growth (Fig. 6). Assuming that there is a selective advantage to repressing DAL gene expression when nitrogen is not limiting, there would have been an incremental selective advantage to relocating each gene into the chromatin modification (HZAD) domain. Thus, one way in which alleles could interact well is by being amenable to the same type of chromatin modification [76].

Fig. 6
figure 6

Activation of expression of the DAL genes. The DAL gene cluster lies within an HZAD domain, in which histone H2A is replaced by the histone variant H2A.Z (Htz1) [83]. H2A.Z protects euchromatin from the ectopic spread of silent heterochromatin (the region of Sir2-effected silencing closer to the telomere), and is present in (and enables expression of) the DAL1, DAL2, DCG1 and DAL3 genes but not DAL4 or DAL7. Interestingly, while DAL1, DAL2, DCG1 and DAL3 are all single copy genes, DAL4 and DAL7 were generated by duplication of progenitor genes that remain at their original sites in the S. cerevisiae genome. The exchange of histone H2A for H2A.Z is mediated by the Swr1 chromatin remodeling complex [182]. The region between the DAL1 and DAL4 genes binds the transcription repressor Sum1, which in turn recruits Hst1 (a paralog of Sir2), which deacetylates histones H3 and H4

Under new selection regimes, adaptations may evolve while established functions may become less important. The GAL genes, which are required for galactose utilization, are clustered in the genomes of every yeast species in which they are present [75]. This pathway converts galactose into glucose-6-phosphate, a substrate for glycolysis. Galactose utilization is widespread amongst yeasts and is likely to be ancestral. However, several yeast species have lost the ability to use this carbon source. Comparisons of the genomes of galactose-utilizing and non-utilizing yeast species have revealed that three out of the four non-utilizing species examined lack any trace of the pathway except for a single gene. However, S. kudriavzevii, a close relative of S. cerevisiae, retains remnants of all seven dedicated GAL genes as syntenic pseudogenes, providing a rare glimpse of an entire pathway in the process of degradation [75]. Thus, whilst a newly formed functional gene cluster confers a selective advantage in a new ecological niche, rapid and irreversible gene inactivation and pathway degeneration can occur under non-selective conditions. It has been suggested for S. kudriavzevii that this change may be associated with adaptation to growth on decaying leaves and soil rather than on sugar-rich substrates [75]. The loss of genes and pathways through reductive evolution has been inferred for many organisms that have adapted to pathogenic or endosymbiotic lifestyles [8592]. Adaptation to a new niche has been shown to result in a “cost” in terms of lost ancestral capabilities. These capabilities may be lost either because they are no longer under selection (neutral) or because of a deleterious effect on fitness in a new niche [75, 9395].

Operon-like gene clusters in plants

Genes for metabolic pathways in plants are generally not clustered, at least for the majority of the pathways that have been characterized in detail to date. However, several examples of functional gene clusters for plant metabolic pathways have recently emerged. These are the cyclic hydroxamic acid (DIBOA) pathway in maize [9698], triterpene biosynthetic gene clusters in oat [99, 100] and Arabidopsis [101] (the avenacin and thalianol gene clusters, respectively), and the diterpenoid momilactone cluster in rice [102, 103]. These gene clusters all appear to have been assembled from plant genes by gene duplication, acquisition of new function, and genome reorganization and are not likely to be a consequence of horizontal gene transfer from microbes. The existence of these clusters, of which at least three are implicated in plant defense [98, 99, 102104], implies that plant genomes are able to assemble functional gene clusters that confer an adaptive advantage. The selection for rapid and recent formation of such metabolic gene clusters is likely to be intense, driven by the need to adapt to growth under different environmental conditions, and implies remarkable genome plasticity.

Benzoxazinoids

The benzoxazinoids are defense-related compounds that occur constitutively as glucosides in certain members of the Gramineae and in some dicots. 2,4-Dihydroxy-1,4-benzoxazin-3-one (DIBOA) is the primary hydroxamic acid in rye while its methoxy derivative 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA) is predominant in maize and wheat [105108]. In the Poaceae, the production of benzoxazinoids is developmentally regulated with highest levels being found in the roots and shoots of young seedlings. The glucosides are hydrolyzed in response to infection or physical damage to produce DIBOA and DIMBOA, which are antimicrobial and also have pesticidal and allelopathic activity. Induction of benzoxazinoid accumulation has also been reported in response to cis-jasmone treatment [109].

The complete molecular pathway for benzoxazinoid biosynthesis has been elucidated in maize (reviewed in [98]). The first committed step towards DIBOA and DIMBOA biosynthesis is the conversion of indole-3-glycerol phosphate to indole, which is catalyzed by the tryptophan synthase α (TSA) homologue BX1. Bx1 is likely to have been recruited from primary metabolism either directly or indirectly by duplication of the maize gene encoding TSA. BX1 and TSA are both chloroplast-localized indole-3-glycerolphosphate lyases (IGLs). BX1 functions as a monomer and produces free indole, while TSA forms a complex with the β-subunit of tryptophan synthase TSB to convert indole-3-glycerol phosphate to tryptophan [97, 110]. The subsequent conversion of indole into DIBOA is catalyzed by four related but highly substrate-specific cytochrome P450s (BX2-5) [96]. The glucosyltransferases BX8 and 9 catalyse glucosylation of benzoxazinoids. The glucosides of DIBOA and DIMBOA have reduced chemical reactivity when compared to the aglycones, suggesting that glucosylation may reduce phytotoxicity and so be important for storage [111]. Glucosylation takes place prior to hydroxylation by the 2-oxoglutarate dioxygenase (2-ODD) BX6 [112] and O-methylation by O-methyltransferase (OMT) BX7 [113]. All the Bx genes with the exception of Bx9 are linked within 6 cM of Bx1 on maize chromosome 4 [97, 111].

The distribution of benzoxazinoids across the Gramineae is sporadic. Maize, wheat, rye, and certain wild barley species are capable of the synthesis of these compounds while oats, rice, and cultivated barley varieties are not [106, 108]. The pathway to DIBOA is conserved in maize, wheat, and wild barley [97, 114117]. The Bx gene cluster is believed to be of ancient origin. Wheat and rye have undergone a shared genomic event that has led to the splitting of the Bx gene cluster into two parts that are located on different chromosomes. This can be explained by a reciprocal translocation in the ancestor of wheat and rye [114]. Bx-deficient variants of a diploid accession of wild wheat Triticum boeoticum have recently been identified. Molecular characterization suggests that Bx deficiency in these accessions arose by disintegration of the Bx1 coding sequence, followed by degeneration and loss of all five Bx biosynthetic genes examined [116]. Barley species that do not produce benzoxazinoids have also lost all Bx genes [114, 117]. The precise physical distances between all of the genes within the Bx cluster are not known. However, in maize, Bx1 and Bx2 genes are 2.5 kb apart [97] while Bx8 is 44 kb from Bx1 [118]. In hexaploid wheat, the Bx3 and Bx4 genes are 7–11 kb apart within the three genomes [119]. Although several of the Bx genes are in close physical proximity this gene cluster appears to be less tightly linked than the other examples that have been considered so far in this review. Interestingly, barley lines that produce benzoxazinoids do not synthesize gramine, a defense compound that is also derived from the tryptophan pathway. Conversely, gramine-accumulating barley species are deficient in benzoxazinoids. This has led to the suggestion that the biosynthetic pathways for these two different classes of defense compound are mutually exclusive, possibly due to competition for common substrates [117].

Outside the Poaceae, benzoxazinoids (in particular DIBOA and its glucoside) are found in certain isolated eudicot species belonging to the orders Ranunculales (e.g., larkspur, Consolida orientalis; yellow archangel, Lamium galeobdolon) and Lamiales (e.g., zebra plant, Acanthus squarrosa) [120]. Comparison of the BX1 enzymes of grasses and benzoxazinone-producing eudicots indicates that these enzymes do not share a common monophyletic origin. Furthermore, the CYP71C family of CYP450s to which BX2-5 belong is not represented in the model eudicot, thale cress Arabidopsis thaliana, and all members of this family described to date originate from the Poaceae. It therefore seems likely that the ability to synthesize benzoxazinones has evolved independently in grasses and eudicots.

Terpenes

Investigation of triterpene biosynthesis in plants has led to the discovery of two other examples of operon-like metabolic gene clusters, namely the avenacin gene cluster in oat (Avena species) and the thalianol gene cluster in A. thaliana [99, 101, 104].

Avenacins are antimicrobial triterpene glycosides that confer broad spectrum disease resistance to soil-borne pathogens [104, 121]. Analysis of the genes and enzymes for avenacin synthesis has revealed that the pathway has evolved recently, since the divergence of oats from other cereals and grasses [99, 100, 122, 123, 186]. Transferal of genes for the synthesis of antimicrobial triterpenes into cereals such as wheat holds potential for crop improvement but first requires the necessary genes and enzymes to be characterized. Synthesis of avenacins is developmentally regulated and occurs in the epidermal cells of the root meristem. The major avenacin, A-1, has strong fluorescence under ultra-violet light and can be readily visualized in these cells. This fluorescence, which is an extremely unusual property amongst triterpenes, has enabled isolation of over 90 avenacin-deficient mutants using a simple screen for reduced root fluorescence [100, 104]. This mutant collection has facilitated gene cloning and pathway elucidation.

Sad1 encodes an oxidosqualene cyclase enzyme that catalyses the first committed step in the avenacin pathway [99, 122], while Sad2 encodes a second early pathway enzyme—a novel cytochrome P450 enzyme belonging to the newly described monocot-specific CYP51H subfamily [100]. Sad1 and Sad2 are likely to have been recruited from the sterol pathway (from cycloartenol synthase and obtusifoliol 14α-demethylase, respectively) by gene duplication and acquisition of new functions [99, 100, 122]. Sterols and avenacins are both synthesized from the mevalonate pathway [124]. While the genes for sterol synthesis are generally regarded as being constitutively expressed throughout the plant, the expression of Sad1, Sad2, and other cloned genes for avenacin biosynthesis is tightly regulated and is restricted to the epidermal cells of the root meristem [99, 100, 122]. Recruitment of Sad1 and Sad2 from the sterol pathway by gene duplication has therefore involved a change in expression pattern as well as neofunctionalisation.

The Sad1 and Sad2 genes are adjacent, and lie ~70 kb apart in the A. strigosa genome [100]. A third gene has recently been cloned and shown to encode a serine carboxypeptidase-like acyltransferase that is required for avenacin acylation. This gene (Sad7) [104, 186] is ~60 kb from Sad1 on the opposite side to Sad2. Four other loci that are required for avenacin synthesis also co-segregate with these cloned genes, indicating that most of the genes for the pathway are likely to be clustered [99]. Since avenacins confer broad spectrum disease resistance, the gene cluster is likely to have arisen through strong epistatic selection for maintenance and co-inheritance of this gene collective. In addition, interference with the integrity of the gene cluster can in some cases lead to the accumulation of toxic intermediates, with detrimental consequences for plant growth, so providing further selection for cluster maintenance [123]. Gene clustering may also facilitate co-ordinate regulation of gene expression at the level of chromatin [2].

The thalianol gene cluster in A. thaliana consists of four contiguous co-expressed genes encoding an oxidosqualene cyclase (THAS), two different types of cytochrome P450 (THAH and THAD), and a BAHD acyltransferase [101] (Fig. 7). THAS, THAH, and THAD catalyze the synthesis and subsequent modification of thalianol. The BAHD acyltransferase gene is predicted to be part of the cluster based on its location and expression pattern, but an acylated downstream product has not as yet been identified. In the related crucifer, A. lyrata, the structure of the BAHD acyltransferase gene is different, and the two BAHD genes are more divergent than the other pairs of genes within these regions (Fig. 7). This may be indicative of paralogy rather than orthology [125]. Alternatively it may indicate that the BAHD acyltransferase genes are not under strong selection and so are divergent. It is noteworthy that there is also a large insertion of >100 kb (consisting mainly of transposons) in the cluster in A. lyrata that is not present in A. thaliana. A. thaliana thalianol pathway mutants do not show any obvious effects on plant defense and the function of the pathway is as yet unknown. However, the THAS, THAH, and THAD sequences are highly conserved across different A. thaliana accessions, implying that the gene cluster confers an important and as yet unidentified selective advantage in this species [101].

Fig. 7
figure 7

The thalianol gene cluster in Arabidopsis. The A. thaliana gene cluster consists of four contiguous co-expressed genes encoding an oxidosqualene cyclase (THAS), two different types of cytochrome P450 (THAH and THAD) and a BAHD acyltransferase [101]. The organization of the equivalent region from the related crucifer, A. lyrata, is shown. The structure of the BAHD acyltransferase gene in A. lyrata is different (indicated by a split gene) and there is a 100-kb insertion in this region. dS number of synonymous substitutions per synonymous site; dN number of nonsynonymous substitutions per nonsynonymous site. Adapted from Ref. [125]

The genes within the A. thaliana thalianol gene cluster are expressed predominantly in the root epidermis, as is the case for the oat avenacin gene cluster [99101]. The THAS, THAH, THAD, and BAHD acyltransferase genes all have marked histone H3 lysine 27 trimethylation, whereas the immediate flanking genes do not, suggesting co-ordinate regulation of expression of the gene cluster at the level of chromatin [101]. As is the case for the avenacin pathway, tight regulation of the pathway appears to be critical since accumulation of thalianol pathway intermediates can impact on plant growth and development.

There are superficial similarities between the avenacin and thalianol gene clusters in that they are both required for triterpene synthesis and contain genes for oxidosqualene cyclases, CYP450s, and acyltransferases. However, phylogenetic analysis indicates that the genes within these clusters are monocot and eudicot specific, respectively, and that the assembly of these clusters has occurred recently and independently in the two plant lineages [101]. This suggests that selection pressure may act during the formation of certain plant metabolic pathways to drive gene clustering, and that triterpene pathways are predisposed to such clustering.

A third example of a gene cluster for synthesis of terpenes in plants has been reported from rice, in this case for synthesis of diterpene defense compounds known as momilactones [102, 103]. Momilactones were originally identified as dormancy factors from rice seed husks and are also constitutively secreted from the roots of rice seedlings. In rice cell suspension cultures and in leaves, expression of the rice momilactone genes can be co-ordinately induced in response to challenge with pathogens, elicitor treatment, or exposure to UV irradiation [102, 103]. Synthesis of momilactones is initiated by terpene synthases that are distinct from the oxidosqualene cyclases that catalyze the first committed step in triterpene synthesis. The 168-kb momilactone gene cluster lies on rice chromosome 4 and consists of two diterpene synthase genes, a dehydrogenase gene and two functionally uncharacterized P450 genes, all of which are involved in/implicated in momilactone synthesis [103]. These genes are all co-ordinately induced in response to treatment with a chitin oligosaccharide elicitor. Analysis of the promoters of the genes within this cluster has revealed the presence of potential recognition sites for WRKY and basic leucine zipper (bZIP) transcription factors, proteins that are associated with activation of defense responses. Gene clustering has been suggested to facilitate efficient coordinated expression of the momilactone gene cluster in response to elicitation [103].

Functions of gene clusters in animal defense and development

Global gene expression analysis has revealed extensive clustering of non-homologous genes that are co-ordinately expressed in eukaryotes, including in animals (for reviews, see [2, 126, 127]). These groups of genes may be expressed during development, or in certain tissues and diseased states, and have been reported in studies of Drosophila, nematode, mouse, and humans. Such co-expression domains may therefore be an important source for the discovery of new functional gene clusters in animals and other eukaryotes. However, more research is needed before we can fully understand the functional significance of co-expression domains [127]. Of the known functional gene clusters in animals, the best characterized is the major histocompatability complex (MHC), which encodes proteins involved in innate and adaptive immunity. Other classes of mammalian gene clusters include the Hox and β-globin loci, which are required for development and for the synthesis of haemoglobin, respectively. The latter two examples consist of genes that share sequence similarity and so are distinct from classical operons and from the functional gene clusters discussed above. However, investigation of these loci has revealed important insights into the mechanisms of regulation of arrayed gene clusters in eukaryotes and so these gene clusters will also be considered here.

The major histocompatability complex (MHC)

The extended human major histocompatability complex (MHC) spans ~7.5 Mb of chromosome 6, contains over 282 protein coding-genes and is the most important immunological region of the human genome [128] (Fig. 8). The MHC was discovered in mouse in 1936 and was investigated for its genetic role in tissue graft and organ transplant compatibility (histocompatibility). It later transpired that the primary function of the classical MHC gene-products was to provide protection against pathogens in innate and adaptive immunity. The MHC has been subdivided into a number of regions: the Class I region which contains the classical HLA Class I family genes that are involved in antigen presentation to CD8 T lymphocytes; the Class III region, which contains diverse immune and non-immune related genes and is the most gene dense region of the human genome; and the Class II region, which is dominated by the HLA Class II family genes that are involved in antigen presentation to CD4 T lymphocytes. The boundaries of the MHC have been pushed out since its discovery to delineate an extended MHC region [128]. Together, immune-related genes make up about 30% of the expressed transcripts in the extended MHC and their gene products function in antigen processing and presentation, inflammation, leukocyte maturation, complement signaling, immune regulation, and responses to stress [128]. However, three of the largest gene families in the extended MHC are not obviously immune-related. These are the tRNA, histone, and olfactory receptor gene families. Histones and tRNAs are required for DNA replication and protein synthesis, and enormous quantities of transcript must be produced to meet the needs of a single cell. Therefore, in the majority of eukaryotes, histone and tRNA genes tend to be found in tandem duplicated arrays that are also regions of high transcription [129]. In the human genome, the largest tRNA and histone gene arrays reside within the extended MHC (comprising 157 and 66 loci, respectively). For this reason, it has been suggested that the immune-related genes of the MHC may be hitchhiking with the histone and tRNA gene arrays, and in doing so benefiting from the inherent high transcriptional activity of the region [128].

Fig. 8
figure 8

The human major histocompatibility complex (MHC). A representation of the distribution of genes from large or immunologically important gene families across the ~7.5 Mb extended MHC on the short arm of human chromosome 6. Each coloured block represents multiple genes and the number of blocks indicates their approximate abundance. Single genes, which are interspersed throughout, are not shown. Also not shown are the 157 tRNA loci that lie in the extended Class I region. The drawing is not to scale

The majority of genes from the MHC class I and III regions are constitutively expressed in all somatic cell types, although expression levels can vary over two orders of magnitude depending on the cell-type or extracellular stimuli [130]. By contrast, genes in the MHC class II region are expressed only in antigen-presenting cells or in other cell-types after induction by cytokines such as interferon-gamma. The Class II gene transactivator (CIITA) acts as a master regulator for the expression of genes in the MHC Class II region. Mutations in CIITA are one of the causes of bare lymphocyte syndrome in humans, a hereditary immunodeficiency disease characterized by a complete lack of MHC class II gene expression. CIITA acts by stabilizing a multi-subunit complex on the promoters of target genes to activate their transcription [131]. Formation of the CIITA-complex results in a large wave of histone acetylation and intergenic transcription that spreads out bi-directionally from the target promoter [132]. CIITA-mediated transcription is highly specific and appears to target only around 25 genes in the human genome, including the HLA Class II family genes within the MHC Class II region, two unrelated genes in the MHC Class I region, and other immune-related genes on different chromosomes [133]. Despite the presence of such specific transcription factors, the physical clustering of genes in the MHC does appear to be important for their regulation. The chromatin fibre of the extended MHC forms extra-chromosomal loops that are periodically anchored to the nuclear matrix at matrix attachment regions (MARs) by MAR binding proteins to form a chromatin “loopscape” [134, 135]. Treatment with interferon-gamma results in remodeling of the loopscape and differential regulation of genes within the affected regions [136]. Remodeling also leads to alterations in the composition of MAR binding proteins associated with the chromatin fibre and the subsequent recruitment of promyelocytic leukemia nuclear bodies, which may act as transcriptional factories for specific chromosomal loci [135, 137].

The origin of the major histocompatibility complex in metazoans is likely to predate the emergence of the jawed fish ~500 million years ago [138]. The MHC region varies greatly in structure and size between species. This diversity is likely to have been driven by adaptive changes in response to selection pressure from pathogens and parasites [138]. The linkage between MHC Class I and Class II genes has been preserved from the cartilaginous fish to humans, except in the bony fish where linkage has disintegrated [138]. The MHC is also highly variable within species; in humans, as many as 300 alleles can be found at a single locus. Some alleles are so divergent that their common ancestor is likely to predate the formation of the species. The MHC is also a site of strong linkage disequilibrium, and large conserved blocks of specific alleles, or haplotypes, of up to 3.2 Mb can be detected [139]. Therefore, particular patterns of MHC alleles may be fine-tuned to work together, and this may be one of the mechanisms by which clustering of the MHC is maintained [126].

A number of regions in the human genome are paralogous to the MHC, and these are thought to have arisen by the duplication and fragmentation of a single proto-MHC after two rounds of whole genome duplication [140]. One of these paralogous regions is the natural killer complex (NKC) [140]—a functional gene cluster that spans >1.5 Mb and contains C-type lectin receptor genes important for natural killer cell (NK) function in addition to other immune related genes. Remarkably, the MHC of chicken contains two C-type lectin receptor genes that are highly homologous to the receptor genes in the human NKC. The presence of these NK receptors in the chicken MHC suggests that the proto-MHC may have contained at least one ancestral C-type lectin receptor gene that was differentially retained at different loci after whole genome duplication in the lineages that gave rise to chicken and man. The leukocyte receptor complex (LRC), which contains a large array of immunoglobulin family NK receptors, is similarly thought to be derived from the proto-MHC [140]. Together, these results suggest that the clustering of immune-related genes at the MHC, NKC, and LRC was not independent, but instead was derived from the more ancient clustering of immune-related genes at the proto-MHC. How the ancestral genes became clustered remains a matter of debate.

Hox genes

Homeotic mutations in animals result in the transformation of one body segment into another and have played a crucial role in shaping our understanding of animal development. In the late 1970s, it was discovered that many homeotic mutations in Drosophila mapped to the Bithorax and Antennapedia complexes [141, 142], complexes that we now know to consist of tandem duplicated arrays of genes encoding homeodomain (Hox) transcription factors [143, 144]. The first ancestral Hox cluster is thought to have appeared before the separation of the Cnidarians and Bilaterians, some 600 million years ago [145]. Diversification of the ancestral cluster facilitated the development of diverse and complex body plans across the metazoa. For example, in mammals, there are four Hox clusters that have arisen through whole genome duplications with up to 14 Hox genes within each cluster.

Expression of Hox genes is regulated in a remarkable fashion. The order of the genes along the chromosome corresponds to the region of expression along the length of the developing animal (spatial collinearity of expression) (Fig. 9). Clustered Hox genes are also activated in a wave that starts from the 3′ most end of the cluster and moves progressively to the 5′ end (temporal collinearity of expression). In some species, the Hox cluster has become disrupted. This is at its most extreme in the tunicate Oikopleura dioica where the Hox cluster has completely disintegrated and the remaining Hox genes are dispersed throughout the genome [146]. Cluster disintegration in O. dioica is accompanied by the loss of temporal collinearity of Hox gene expression. However, the spatial expression pattern of the Hox genes appears to be largely maintained. Through comparisons with other species lacking complete Hox clusters, it appears likely that cluster disintegration marks a switch to a more rapid life-cycle and a determinative mode of development where cell fate is fixed and flexible Hox regulation is no longer required [146]. Physical linkage of the Hox genes therefore appears to be important for choreographing Hox expression.

Fig. 9
figure 9

Confocal image of septuple in situ hybridization exhibiting the spatial expression of Hox gene transcripts in a developing Drosophila embryo, with the chromosomal organization of the Hox gene cluster shown below: lab labial, pb proboscipedia (not shown in the in situ hybridization), Dfd deformed, Scr sex combs reduced, Antp antennapedia, Ubx ultrabithorax, Abd-A abdominal-A, Abd-B abdominal-B. The in situ hybridization image has been reproduced with permission from [183]

Retinoic acid (RA), a vitamin A-derived morphogen, can stimulate the sequential induction of Hox genes [147]. RA stimulation is mediated through a conserved retinoic acid responsive element (RARE) upstream of the 3′ most Hox gene, Hox1. Through the course of embryonic development, conserved RAREs upstream of progressively 5′ Hox genes propagate a wave of induction across the Hox cluster. Components of the RA signaling pathway either predate the Hox cluster or appeared shortly after its emergence, suggesting that temporal collinearity of expression may be an ancestral feature of the Hox cluster [148]. The sequential activation of Hox genes in different metazoans is accompanied by directional changes in histone modifications, the opening up of the chromatin, and in some cases looping out of the chromatin fibre [126]. The orchestration of this complex series of events is still not fully understood. Transcriptional repression of Hox genes through histone modifications and chromatin condensation is equally important for the establishment of appropriate Hox expression domains. Hox expression can in addition be controlled post-transcriptionally and perhaps also epigenetically by non-coding RNAs and micro RNAs (miRNAs), the genes for which are embedded in the Hox cluster [149].

The β-globin gene cluster

Cis-regulated clusters of structurally related genes such as the Hox cluster are a recurring feature of animal genomes. The β-globin cluster is a particularly well-characterized example which has provided many insights into cis-regulation of gene expression in eukaryotes (for other examples, see [150]). The mouse β-globin cluster contains four related functional genes, Ey, βH1, βmajor, and βminor, encoding β-globin polypeptides that combine with α-globin polypeptides to form the haemoglobin tetramer. The β-globin genes are differentially expressed through development; and βH1 are expressed in embryonic/fetal erythroid cells and βmajor and βminor are expressed in the adult [151] (Fig. 10). Upstream of the β-globin genes are a number of DNase hypersensitive sites (HSs), indicating the presence of regions of low nucleosome density and enhanced chromatin accessibility [152]. A cluster of four upstream HSs comprise a type of enhancer known as a locus control region (LCR). An LCR is defined as a sequence that is able to confer copy number-dependent and position-independent expression of a transgene. The β-globin LCR was the first to be described [151]. Deletion studies in humans and mice have shown that the LCR is required for high level expression levels, but that when used to drive expression of a transgene it cannot recapitulate the tissue-specific developmental expression pattern of the β-globin genes. Expression from the β-globin cluster is accompanied by dynamic changes in both permissive and repressive histone modifications which are at least in part mediated by trans-acting factors such as the zinc-finger DNA binding transcription factor GATA-1 and the SWI/SNF chromatin remodeling complex [151] (Fig. 10). The intergenic transcription that occurs across the β-globin locus has also been proposed to play a role in the establishment of the histone pattern via polymerase II or RNAi dependent mechanisms [151]. Interestingly a major proportion of this intergenic transcription is actually initiated at the β-globin LCR [132].

Fig. 10
figure 10

The mouse β-globin locus. The four mouse β-like globin genes are located downstream of an array of DNAse I hypersensitive sites (vertical bars). The first four DNAse I hypersensitive sites upstream of form the locus control region (LCR). Activation of the βmajor locus occurs in four steps [151, 184]: (I) an LCR subcomplex is assembled over the LCR; (II), (III) GATA-1 occupies the LCR and βmajor promoter and recruits the SWI/SNF chromatin remodeling complex; and (IV) SWI/SNF-dependent chromatin looping and final assembly of the promoter complex occur simultaneously, and are followed by recruitment of Pol II and activation of βmajor transcription. Adapted from [184]

Classical operons in eukaryotes?

In the early 1990s, structures with remarkable similarities to classical prokaryotic operons were discovered in the genome of the nematode Caenorhabditis elegans [153, 154]. We now know that 15% of genes in C. elegans are organized into such operons. These operons consist of linked genes that are under the control of a single promoter and are transcribed as a single polycistronic mRNA [155, 156] (Fig. 11). However, unlike the situation in prokaryotes, this polycistronic mRNA is then trans-spliced into monocistronic mRNAs that are translated individually. In trans-splicing, a donor splice-leader RNA donates a short leader sequence to a splice acceptor site within the polycistronic mRNA that becomes the 5′ end of a mature monocistronic mRNA. Genes within C. elegans operons are rarely related by sequence or function, and housekeeping and constitutively expressed genes are over-represented [155157]. This suggests that C. elegans operons arose in situ without gene duplication or genome rearrangement and therefore that these operons are of a fundamentally different nature to the majority of prokaryotic operons and also to functional gene clusters in eukaryotes. The adoption of trans-splicing is likely to be the key event that led to the flourishing of operons in nematodes. The benefits offered by trans-splicing are not well understood, but once established, this mRNA processing mechanism appears to favor operon formation and maintenance [158160]. Operon breakup may be disfavored because downstream genes within an operon usually lack promoters and so are unlikely to be expressed following segmental duplication or disruption of the operon. Beyond the nematodes, trans-spliced operons have been detected in the genomes of several other animals including the tunicates Oikopleura dioica and Ciona intestinalis [161163] and the chaetognath arrow worm, Spadella cephaloptera [164]. It has been predicted that operons may be present in all species able to carry out trans-splicing [165]. The origins of trans-splicing are unclear, and the scattered distribution of this mechanism across the animal kingdom could be due to convergent evolution or to extensive loss of an ancient feature [166]. A number of operon-like structures have also been identified in Drosophila, which lacks the trans-splicing machinery. Some Drosophila operons produce dicistronic mRNAs that are translated directly [167169] while others, such as the lounge lizard (llz)/CheB42a locus produce a bicistronic pre-mRNA that is processed to produce two monocistronic mRNAs [170]. Subsequent bioinformatic analysis identified 409 Drosophila gene pairs that may also produce bicistronic mRNA [170]. Unlike C. elegans, the operons identified in Drosophila commonly contain genes with related functions and/or sequence similarity, and mRNA processing does not involve trans-splicing. Further research is required to determine whether Drosophila has particular mechanisms in place that promote operon formation. Operon-like loci have also been identified in mammals [171174], plants [175177], and the filamentous fungi [178]. The small number of examples identified so far would suggest that such structures are very rare in the genomes of these intensively studied organisms.

Fig. 11
figure 11

Different strategies for the processing of eukaryotic operons. a The operons of Caenorhabditis elegans produce a polycistronic pre-mRNA that is processed into two or more mature monocistronic mRNAs by the trans-splicing machinery. The spliced leader sequence (black box) is derived from a spliced leader (SL) RNA which carries the 5′ RNA cap (circle) [156]. b Alternative splicing of a polycistronic pre-mRNA can produce two mature mRNAs with a common first exon (white box) as observed at the conserved cholinergic locus [185]. c In some cases, such as for the Drosophila stoned locus, mature polycistronic mRNAs can be translated directly [167]. The downstream CDS is likely to be translated through ribosome reinitiation, leaky scanning or internal ribosome entry. d Also in Drosophila, at least one polycistronic pre-mRNA is spliced via a novel mechanism that results in a conventional capped monocistronic mRNA for the upstream gene and an uncapped monocistronic mRNA for the downstream gene [170]. The uncapped transcript is stable and appears to be translated

Conclusions and perspectives

Here we have reviewed the literature on gene clusters in prokaryotes and eukaryotes, with particular emphasis on functional gene clusters. This theme is very broad and inevitably we have not been able to cover the entire swathe of literature in this field. We apologise to those whose work we have not cited. Nevertheless, we hope that by bringing together different and disparate facets of this area we have been able to highlight some of the similarities and differences between the ways in which gene clusters are organized and regulated in different organisms. The reasons for gene clustering can be considered at both the functional level and at the population level. These two considerations are not mutually exclusive [179]. Considering the population level first, where the fitness of an allele at one locus depends on the genotype at another locus then a selective advantage may arise for genomic rearrangements that reduce the distance between the two loci [180]. Significantly, this ratcheting effect may be enhanced when the fitness of recombinant haplotypes is low, for example where the combination of a functional and non-functional allele at two loci results in the premature disruption of a biochemical pathway and accumulation of toxic intermediates [76, 123, 181]. Operons or gene complexes can thus be regarded as units of strong gene interaction, with tightening of linkage between structural genes [179]. The selection for new gene clusters is likely to be intense, driven by the need to adapt to growth under different environmental conditions. At the functional level, physical clustering may be advantageous because it allows groups of genes to be co-ordinately regulated at the levels of nuclear organization and/or chromatin. Thus, one way in which alleles could interact well is by being co-localized in regions of chromosomes that facilitate co-ordinate regulation at this level and by being amenable to the same type of chromatin modification. In the future, it is likely that in-depth analysis of the levels at which functional gene clusters are post-transcriptionally regulated will reveal new facets of co-ordinate regulation that will shed further light on the mechanistic benefits of physical clustering.