Vertebrate Gene Origins: Difference between revisions

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Small scale duplicon-driven inversions and duplications, often at homoplasic hotspots, go into the evolutionary hopper at nearly every childbirth. This greatly raises the odds that some will be fixed as near-neutral. Over vast evolutionary times, this could produce the many paleo-paralogons we observe today in the mammalian genome rather than paleo-polyploidy.
Small scale duplicon-driven inversions and duplications, often at homoplasic hotspots, go into the evolutionary hopper at nearly every childbirth. This greatly raises the odds that some will be fixed as near-neutral. Over vast evolutionary times, this could produce the many paleo-paralogons we observe today in the mammalian genome rather than paleo-polyploidy.
=== Tetraploid mammal faces oblivion ===
Polyploidy is quite important for understanding the evolutionary potential of the human genome. It has long been believed that polyploidy played less of a role in animal evolution than plants, the explanation (White, 1973) being chromosomal sex determination and obligatory cross-fertilization in addition to gene dosage issues. Bisexual polyploidy seemed to have stopped with the 12 known species of polyploid amphibians, with no polyploid amniote (much less mammal) ever documented.
If so, whole genome duplication has played no role in mammalian evolution over the last 400 million years and is '''not even an available mechanism''' for gene family expansion for in this lineage -- whole genome duplication is at best a paleo-process.
Consequently it came as a great surprise when Nature published a paper in 1999 asserting tetraploidy in a hystricognath rodent, Tympanoctomys barrerae. Four followup papers from the same group appeared over the next ten years in J Evol Biol, Biol Research and Genomics, culminating in an [http://www.ncbi.nlm.nih.gov/pubmed/18758856,16580173,15586825,14635891 August 2008 paper] in Mammalian Genome reporting tetraploidy in a second genus Pipanacoctomys.
[[Image:TetraMammNot.jpg|left|]]
Midway, a thorough experimental [http://www.ncbi.nlm.nih.gov/pubmed/15780745 paper from karyotyping experts] appeared in Genomics in 2005 entitled " Molecular cytogenetics discards polyploidy in mammals".  As that journal never releases its articles online, the expense of reprints dimished the article's impact. Perhaps it contained some technical error since the tetraploidy authors and journal peer-reviewers seemed to ignore it subsequently. According to downstream google search, mammalian tetraploidy is a done deal.
Yet the senior author of the 2005 paper has published 86 previous papers over 25 years in mammalian karyotypic phylogenomic analysis, so can be assumed familiar with best contemporary experimental methods and their potential pitfalls. Contacted by email in Sept 2008, the authors confirm that nothing has changed their view that Tympanoctomys barrerae is an ordinary diploid with extensive repeats that simply don't respond to C-banding (nothing new there).
The experimental evidence for T. barrerae diploidy is overwhelming. No form of tetraploidy -- autotetraploidy or allotetraploidy (two-species hybrid) -- is consistent with the data. Every chromosome has two copies: that is diploidy. The experimental approaches includes painting by separated chromosomes of closely related diploid Octodon degus as well as human and mouse FISH, G-banding, C-banding, meiotic studies, nucleolus organizer region, whole genome karotyping and effects of amplified heterochromatin repeat size heteromorphismon hybridization, as well as fragmented but not duplicated ancestral syntenies.
Moving on from this particular non-debate, we could ask if some other tetraploid amniote might be discovered: yet thousands (admitedly not all) of extant species have been karyotyped. This represents over ten billion years of branch length years with no tetraploidy observed to date and none expected on theoretical grounds. Recent paleopolyploidy is impossible in any of the 30 sequenced mammlian genomes on all-vs-all blastp grounds.
Chromosome painting should not be dismissed quite yet as buggy-whip technology in the genomic era (which is yet to complete a single deuterostome genome). The resolution may be low (4 mbp) but it has two very great advantages: truly complete genomes and lots of them. That plays out in a recent paper thrashing the bioinformatics of inversion as applied to [http://www.ncbi.nlm.nih.gov/pubmed/16510895,15590940,16510896 mis-assembled chicken.]
By karyotyping many genomes, it becomes possible to scan for symplesiomorphic species (such as Xenarthra) that retain a high proportion of ancestral gene order, rather than scrambled genomic species like [http://genome.cshlp.org/cgi/content/full/18/9/1530 gibbon] that confuse more than inform reconstruction efforts.
Genomics has retained its traditional focus on boutique model organisms and rarely surveys for sensible species (Callorhinchus and Fugu being the exceptions). That needs to change because species with slowly evolving gene sequences are a far better guide to the origin of vertebrate genes.
To summarize, whole genome duplication never occured during amniote evolution and was never an option. It is a paleo-process at best, irrelevent to recent vertebrate gene histories.


[[Category:Comparative Genomics]]
[[Category:Comparative Genomics]]

Revision as of 18:19, 25 September 2008

The Origin of Vertebrate Genes

Introduction to gene families

Contemporary vertebrates genomes contain about 20,000 coding genes, not many more than pre-Bilatera and far fewer than was believed prior to the genomic era. These genes fall into perhaps 3000 gene families each with its own history of expansion and contraction, so sizes today vary from singletons to over a thousand members We wish to track each of these gene histories back to the last ancestral genome in which a parental gene was present without additional homologs.

There can be no single sweeping explanation of gene family histories because several gene duplication mechanisms have been continuously at work over an extended time frame. However histories can overlap to a degree when unrelated gene family members are duplicated or deleted in a contiguous block. Shared history can also be less than the full length gene in the case of ubiquitous domains, internal tandem expansions and multi-domain chimeric proteins, complexities not considered further here.

Because convergent homology of sequences and folds is immensely implausible, gene families with multiple members clearly experienced a history of net gene duplication (gains outpacing losses). But singleton genes too may have a significant duplication history when gene loss of their paralogs is considered. For completeness, we should also consider ghosted proteins present in humans today only as pseudogene debris (or gone entirely and only inferred in an ancester from continuing presence in other extant mammals, amniotes, or vertebrates).

Gene loss processes are quite significant, with human a net loser in gene count over the last 310 myr, contrary to cultural narratives assuming 'progress' towards 'complexity' as a given. It's well-known that human sensory genes (olfaction and vision) have been decimated but the list hardly stops there.

Definition of gene family

The specification of gene family is quite subtle because any practical operational definition is limited by sensitivity and the arbitrariness of phylogenetic depth for coalescence cut-off. This is illustrated by a simple gene family, the sulfatases. The 17 paralogs in human, surely the final count because of completeness of that genome and definitive probes, cluster quite distinctly within all-vs-all blastp searches and are readily organized by sequence and exon pattern conservation into a conventional gene tree whose duplications can be timed relative to various ancestral divergences of the metazoan lineage relative to human.

Yet when 3D structures at PDB are consulted, it becomes undeniable that sulfatases and alkaline phosphatases are structurally homologous over their entire length despite a complete lack of convincing primary sequence alignability even by profile. Fold convergence can and does occur (eg TIM beta barrels) but here the fold is so complex, unconventional and isolated in fold space that coincidental arrival at this common structure can be dismissed out of hand. That conclusion is independently validated by colocalization of active sites and similarity of catalytic mechanism (hydrolysis of ester) despite lack of post-translational modification to formylglycine in any phosphatase.

Consequently, the 4 phosphatase paralogs (comprised of a tandem triple on chr2 and an isolated gene on chr1) bring the human gene family size to 21 if we admit gene convergence back to common ancester of human with bacteria. The cut off at Ur-metazoan would keep these gene families separate (and even slightly partition the phosphatase group). Future methods might require coalescence with ever more subtly related gene families. Once a genome is sequenced, blastp becomes available across it; however tertiary structure determination of entire proteomes is not yet in sight.

The small gene family consisting of PRNP and PRND is also instructive. Although in parallel tandem position and clearly homologous despite deletions of the 40 residue repeat in the latter, the relatively short length of 255aa, compositional simplicity in some regions, and percent blastp identity in the 20's invariably causes pipeline clustering procedures to miss the family association.

This gene family also illustrates the total folly of attempting to date duplications -- it's not particularly ancient despite the great divergence. Compare this to a histone that differs at one residue between human and garden pea. PRND can only be traced to amniote by all-out hand curation; it is cleanly deleted in a gapless chicken contig but fortunately a second node representative (lizard) retained it.

PRNP tracks back to teleost fish but again only using tools such as syntenic flanking genes and secondary structure can establish this because fish experienced an astonishing internal expansion amino terminally. The gene didn't necessarily originate in teleosts but to date it has proven impossible to find it chondricthyhes or earlier diverging species because conserved residues have been swamped out.

Chromosomal adjacency and broader synteny are thus be important in determining the gene tree. Sequence algorithms alone can get it wrong. That's seen quite dramatically in GPCR transducins, in which 10 genes occur in tandem pairs. Clearly these didn't come together by random rearrangement. Tandem pairs often separate rapidly in sequence because they must take on distinct roles to be supported by selection.

TransducinGT.jpg

The transducins also illustrate the fallacy of parsimony. Gene families are a product of history, not statistics. That history is often but not always the most parsimonious -- Occam's razor cuts both ways. The third panel at left shows the correct history.


Gene families can also be exceedingly simple. Homogentisate 1,2-dioxygenase, HGD, is as simple as they get. It catalyzes an intermediate step in aromatic amino acid catabolism; without it, a toxic metabolite accumulates. This gene has apparently not been lost from any eukaryotic lineage nor fixed a duplicate or processed pseudogene in 50 billion years of branch length. Sequence conservation is high; there is never ambiguity with blast searches.

Yet HGD illustrates another pitfall in defining gene families. The most recent human genome assembly (NCBI Build 36.1) has a left-over 500 kbp piece of DNA that did not fit into the regular assembly (for unknown reasons). This piece on chr3_random:18,988-73,308 would give rise to an artefactual paralog of HGD with automated procedures, in effect doubling gene family size. Such problems are rare in near-complete genomes such as human but all too common in lower coverage assemblies.

Bad gene names complicate the task

Three sources of gene terminology error makes these histories harder to explain:

  • The term 'gene copy' is sometimes used for what are really deeply diverged paralogs with dimly related functions; gene duplication processes can make highly inexact and inequivalent copies right at the event (so they are never copies), subsequent evolutionary trajectories (other than gene conversion) only dilute the comparison further.
  • The Greek prefix 'iso' is used consistently throughout science to mean 'same'; hence 'isoform' is highly inappropriate for products of distinct diverged genes or alternative splicings of a single gene (the vast majority of which are transcriptional artefacts to begin with). This useage perpetuates long-gone days of starch gel electrophoresis, an experimental technique that could only distinguish enzymatic forms if surface charge happened to differ.
  • The lack of awareness or refusal of authors to comply with agreed-upon international conventions for gene nomenclature (HUGO) causes many downstream problems. Gene names in the genomic era need to stay clear of subscripts, superscripts, mixed Roman and Greek letters, single or double letters, unreadable italics, lower case denoting mouse, easily confused i's and 1's (or o's and 0's), lab jokes, contrived acronyms, and naming by soon-forgotten experiment, tissue expression, end phenotype, or common disease symptom.

It's all been tried before and it doesn't work. There's a reason why Linnaean genus-species nomenclature took over for the species tree -- it's anchored in evolution. Gene trees too can have evolution-based nomenclature, say 3-4 letters to denote gene family, numbered paralogs after that (hopefully by sequence relatedness), and suffixed with a species code adequate for comparative genomics (as in SUMF2_homSap).

This creates a unique hierarchical identifier that works for Google, PubMed, and GenBank searches. It clusters members of gene families by name and extends to the many-genome era. With complete genomes, we are in a position to create stable nomenclature, imperfect perhaps but much improved. Gene terminology need not be immutable (Linnaean taxonomy certainly is not), but proposed improvements have a burden of published proof.

It's quite feasible to have global update cycles at browser centers that generate and maintain synonymy lookup tables at the same time. However 9 vertebrate gene families in 10 could be named forever stably today. For example, the official gene sets at UCSC and Ensembl assign genes random unmemorable alphanumeric strings such as uc003emt.1 (to serve as indexing fields in immense relational databases). We see already with opsins that strings for a gene family are entirely unrelated: uc003emt.1 uc003vnt.2 uc004fjz.2 uc001hza.1 uc003hzv.1.

Since geneSorter resource at UCSC *already* carries the all-vs-all blastp data needed for a quick gene tree as well as the requisite associated column for HUGO name, the uc and version number could be moved to the rear (.uc1, .uc2,...) and the 6 free characters be used for a gene tree-driven nomenclature that incorporates Hugo names to the extent these are available and unambiguous.

The nomenclatural problem has immense practical impacts in synteny. Relationships that should jump out from name along are instead obscured. For example, flawed gene names mask the extent of human paralogons on chr15, chr9, and chr19 -- gene names of close human paralogs often bear no resemblance (eg PRUNE and ATCAY). Comparative genomics in other mammals brings in still other names (more commonly no name) and uninformative transcript or RefSeq strings. It's not a sustainable practise.

Have vertebrate coding genes increased over time?

The number of coding human genes is still not known (Oct 2008) to within 1500-gene accuracy even seven years after sequencing. In fact, no such effort is even underway. Official compilations miss ordinary enzymes like COMT2 (transcribed only in special cells of inner ear) yet still include gravely decayed pseudogenes (that still have spliced transcripts) and non-genes (supported by transcript noise but no comparative genomics even to chimp). Beyond that, weak gene models may guess at initial methionines, lack stop codons and propose impossible alternate splices missing structurally essential core exons, active sites and any phylogenetic support.

Despite these limitations, it's worth compiling gene counts from original articles describing new genome assemblies and as subsequently amended. Being gene counts for contemporary species, they don't directly provide ancestral gene counts at divergence nodes. Yet since no trend whatsoever relates depth of divergence or simplicity of body plan with diminished gene count, ancestral counts may not be so different.

The scientific literature contains some incredulous assertions in the scientific literature about gene counts. If salmon truly experienced four rounds of whole genome duplications since cephalochordate, that implies (neglecting gene loss between rounds and gene gain in Branchiostoma) 350,400 coding genes. Yet the immense collection of salmon cDNA shows no indication whatsoever of any such growth in gene family size. On the contrary, salmon gene count seems very similar to every other vertebrate, as do all of the supposed 3R teleost fish. Their genomes show roughly 20,000 genes, nowhere near the 175,200 expected. How could mature gene-finding algorithms miss 155,200 coding genes given strong known paralogs?

Large-scale gene loss between rounds of duplication reduces the paradox somewhat, yet duplication followed shortly by loss of half the genes seem largely irrelevent to contemporary gene histories, like counting trees falling in the forest that got back on the stump.

Fish genomes have an astronomical numbers of gaps as of October 2008 assemblies. Unbridged gaps in particular imply a great many chromosomal misplacements. It is exceedingly premature to consider global syntenic relationships in a situation with 23,322 unbridged gaps because no known method can distinguish whole genome duplication from the steady accrual of ordinary segmental and re-translocated tandem duplications.

To the contrary, genome sequencing projects show if anything a decreasing trend in gene count in more recently emerging deuterostomes. For example, sea urchin genome has 23,300 coding genes whereas humans have but 20,176 in the 11 Sept 2008 tally of consensus CDS and even this number seems to be inflated over the 17,052 distinct locus count by assignment of multiple CCDS IDs numbers to single genes.


GeneCountPhylo.jpg


Tree generated at Phylodendron by the following Newick string and peer-reviewed literature compilation:
(monBre_09200,(triAdh_11514,(nemVec_18000,(((apiMel_10157,droAve_15827),triCas_16404),
(strPur_23300,(braFlo_21900,(petMar_unknow,(calMil_unknow,((danRer_20322,((tetRub_19602,takRub_18523),

(gasAcu_20716,oryLat_20141))),(galGal_21500,(monDom_19000,homSap_20047)))))))))));

Species Assembly  Gaps  Unbridged  #Genes  Organism
homSap  Mar 06     387     373     20,047  Homo sapiens (human)
monDom  Jan 06  72,803   5,336     19,000  Monodelphis domesticus (opossum)
galGal  May 06  78,478  17,335     21,500  Gallus gallus (chicken)
anoCar  Feb 07  43,237      ND         ND  Anolis carolinensis
danRer  Jul 07  49,727  11,857     20,322  Danio rerio (zebrafish)
tetNig  Feb 04  25,763  23,322     19,602  Tetraodon nigroviridis (pufferfish)
takRub  Oct 04  7,213    7,213     18,523  Takifugu rubripes (fugu)
gasAcu  Feb 06  16,945   1,913     20,716  Gasterosteus aculeatus (stickleback)
oryLat  Apr 06 134,426   8,131     20,141  Oryzias latipes (medaka)
calMil  Dec 06      ND      ND         ND  Callorhinchus milii (eshark)
petMar  Mar 07 202,409      ND      unpub  Petromyzon marinus (lamprey)
braFlo  Mar 06  94,815   3,031     21,900  Branchiostoma floridae (amphioxus)
cioInt  Mar 05  22,521      ND     20,141  Ciona intestinals (tunicate)
strPur  Sep 06  80,391      ND     23,300  Strongylocentrotus purpuratus (urchin)

monBre_09,200 Monosiga brevicollis 
triAdh_11,514 Trichoplax adhaerens
nemVec_18,000 Nematostella vectensis
apiMel_10,157 Apis melifera
triCas_16,404 Tribolium castenatum
droAve_15,827 Drosophila 12_species
strPur_23,300 Strongylocentrotus purpuratus 
braFlo_21,900 Branchiostoma floridae
petMar_unknow Petromyzon marinus
calMil_unknow Callorhinchus milii
danRer_20,322 Danio rerio
tetRub_19,602 Tetraodon nigroviridis
takRub_18,523 Takifugu rubripes
gasAcu_20,716 Gasterosteus aculeatus
oryLat_20,141 Oryzias latipes
galGal_21,500 Gallus gallus
monDom_19,000 Monodelphis domestica
homSap_20,047 Homo sapiens

Gene dosage issues

Gene duplication has the initial effect of increasing gene dosage in mammals. That might seem fairly innocuous in view of various homeostatic feedback mechanisms that might adjust expression and activity to whatever level is optimal. As duplicates are assimiliated over time (sub- and neo-functionalization) the extra copies are then important sources of adaptive innovation and complexification.

However gene dosage diseases (eg Patau and Down syndromes) emerge just from partial trisomy of small chromosomes, suggesting feedback mechanisms cannot always compensate for increased gene dosage. (Note many karyotypic abnormalities in humans have no phenotypic sequalae.) The evolution of sex chromosomes in theran mammals evidently raised gene dosage issues because we observe extensive dose compensation mechanisms fixed for chrX genes such as processed retrogenes on autosomals and random X inactivation.

Although the mammalian genome is peppered with small and large paralogons (segmental duplications of multiple coding genes) of all age classes, there may still be strong constraints on paralogon possibilities. We may only see the ones that offered both immediate and longterm selective advantages not offset by gene dosage ills. Many older paralogons are today a mix of retained duplicates and singletons where a gene has dropped out from one paralogon. The best explanation of this phenonenon (pre-adaptation arising from multifunctionality) has been supplied by Piatigorsky.

Whole genome duplication is potentially more benign vis-a-vis gene dosage that other modes of gene duplication because the entire scattered genomic regulatory apparatus is also duplicated, possibly facilitating homeostasis. Yet experimentally induced tetraploidy in mouse is invariably lethal in early embryonic development. Reports of tetraploidy in other rodents are demonstrably false (see below).

If one believes internet twitter, two rounds of whole genome duplication occured in the vertebrate lineage. Here it is worth noting the highly preliminary genome assemblies of lamprey and elephantshark, the critical two nodes beyond cephalochordate and urochordate. These assemblies completely omit many expected genes in their trace archive coverag; assembled contigs are typically of sub-gene length and contain a small fraction of expected exons. It is very difficult to assembly whole genes from several independent contigs since this could easily chimerize paralogs. As the next node, teleost fish, is greatly confused by large-scale paralogons, the entire discussion seems premature.

We have to wonder how non-tetraploid Branchiostoma could have more coding genes that supposedly octaploid fish. It could equally be argued that whole genome duplication is a mechanism to reduce gene count.

Large scale duplications (a lot of gene dosage coming on board suddenly) is very difficult to disentangle from gradual incremental gene family gain and loss arising from segmental and tandem duplication, given the extent of scrambling from inversions, fusions, and fissions. For example, humans have 6 pericentric inversions and a chr fusion just relative to chimp. A lot of macro-variation is observed just one human to the other.

Small scale duplicon-driven inversions and duplications, often at homoplasic hotspots, go into the evolutionary hopper at nearly every childbirth. This greatly raises the odds that some will be fixed as near-neutral. Over vast evolutionary times, this could produce the many paleo-paralogons we observe today in the mammalian genome rather than paleo-polyploidy.

Tetraploid mammal faces oblivion

Polyploidy is quite important for understanding the evolutionary potential of the human genome. It has long been believed that polyploidy played less of a role in animal evolution than plants, the explanation (White, 1973) being chromosomal sex determination and obligatory cross-fertilization in addition to gene dosage issues. Bisexual polyploidy seemed to have stopped with the 12 known species of polyploid amphibians, with no polyploid amniote (much less mammal) ever documented.

If so, whole genome duplication has played no role in mammalian evolution over the last 400 million years and is not even an available mechanism for gene family expansion for in this lineage -- whole genome duplication is at best a paleo-process.

Consequently it came as a great surprise when Nature published a paper in 1999 asserting tetraploidy in a hystricognath rodent, Tympanoctomys barrerae. Four followup papers from the same group appeared over the next ten years in J Evol Biol, Biol Research and Genomics, culminating in an August 2008 paper in Mammalian Genome reporting tetraploidy in a second genus Pipanacoctomys.

TetraMammNot.jpg

Midway, a thorough experimental paper from karyotyping experts appeared in Genomics in 2005 entitled " Molecular cytogenetics discards polyploidy in mammals". As that journal never releases its articles online, the expense of reprints dimished the article's impact. Perhaps it contained some technical error since the tetraploidy authors and journal peer-reviewers seemed to ignore it subsequently. According to downstream google search, mammalian tetraploidy is a done deal.

Yet the senior author of the 2005 paper has published 86 previous papers over 25 years in mammalian karyotypic phylogenomic analysis, so can be assumed familiar with best contemporary experimental methods and their potential pitfalls. Contacted by email in Sept 2008, the authors confirm that nothing has changed their view that Tympanoctomys barrerae is an ordinary diploid with extensive repeats that simply don't respond to C-banding (nothing new there).

The experimental evidence for T. barrerae diploidy is overwhelming. No form of tetraploidy -- autotetraploidy or allotetraploidy (two-species hybrid) -- is consistent with the data. Every chromosome has two copies: that is diploidy. The experimental approaches includes painting by separated chromosomes of closely related diploid Octodon degus as well as human and mouse FISH, G-banding, C-banding, meiotic studies, nucleolus organizer region, whole genome karotyping and effects of amplified heterochromatin repeat size heteromorphismon hybridization, as well as fragmented but not duplicated ancestral syntenies.

Moving on from this particular non-debate, we could ask if some other tetraploid amniote might be discovered: yet thousands (admitedly not all) of extant species have been karyotyped. This represents over ten billion years of branch length years with no tetraploidy observed to date and none expected on theoretical grounds. Recent paleopolyploidy is impossible in any of the 30 sequenced mammlian genomes on all-vs-all blastp grounds.

Chromosome painting should not be dismissed quite yet as buggy-whip technology in the genomic era (which is yet to complete a single deuterostome genome). The resolution may be low (4 mbp) but it has two very great advantages: truly complete genomes and lots of them. That plays out in a recent paper thrashing the bioinformatics of inversion as applied to mis-assembled chicken.

By karyotyping many genomes, it becomes possible to scan for symplesiomorphic species (such as Xenarthra) that retain a high proportion of ancestral gene order, rather than scrambled genomic species like gibbon that confuse more than inform reconstruction efforts.

Genomics has retained its traditional focus on boutique model organisms and rarely surveys for sensible species (Callorhinchus and Fugu being the exceptions). That needs to change because species with slowly evolving gene sequences are a far better guide to the origin of vertebrate genes.

To summarize, whole genome duplication never occured during amniote evolution and was never an option. It is a paleo-process at best, irrelevent to recent vertebrate gene histories.