Opsin evolution: key critters: Difference between revisions

From genomewiki
Jump to navigationJump to search
No edit summary
No edit summary
Line 4: Line 4:
When the eye is reduced to a single pigment cell backing a single photoreceptor cell, the opsin of that species will be expressed only in one cell of the entire body. In this situation, the opsin may never show up in transcript collections, even with subtraction of common ones.
When the eye is reduced to a single pigment cell backing a single photoreceptor cell, the opsin of that species will be expressed only in one cell of the entire body. In this situation, the opsin may never show up in transcript collections, even with subtraction of common ones.


Vertebrates could never have evolved cilliary opsin vision had the bilateran ancestor possessed the limited opsin repertoire of fruit fly. Thus most pressing question is -- assuming rhabdomeric opsins were thoroughly entrenched in the earliest imaging eyes and photoreception systems -- what kept ciliary opsins around in early bilatera (and even cnidaria) so that they could later be co-opted for ciliary opsin-based vision? We could also ask why vertebrates did not stay on the rhabdomeric track of early deuterostomes but instead underwent this profound switch to the 'untested' ciliary track. It is not at all clear what advantages ciliary offers over rhabdomeric -- ever miss swatting a fly?
Vertebrates could never have evolved cilliary opsin vision had the bilateran ancestor possessed the limited opsin repertoire of fruit fly. Thus most pressing question is -- assuming rhabdomeric opsins were thoroughly entrenched in the earliest imaging eyes and photoreception systems -- what kept ciliary opsins around in early bilatera (and even cnidaria) so that they could later be co-opted for ciliary opsin-based vision? We  
 
ttp://genomewiki.ucsc.edu/index.php/Opsin_evolution:_trichromatic_ancestral_mammal here too] that contemporary tunicates, lancelets, and lamprey are not ancient, ancestral, antiquated, archaic, character-retaining, dead-end, failed experiments, frozen in time, genetically stationary, living fossil, primitive, primordial, relic, or  retro species. They're full modern -- the tree of life is right-justified. Indeed their genes, regulatory signalling systems, and enzymes may be more finely honed than mammals because of more rapid evolution attributable to larger effective population sizes, reproductive mode, generation time, and marine selective predatory pressures.
Fossil dna does not go back nearly this far back, the nearly non-existent fossil record of soft body parts is unhelpful, and transcripts plus genomes of living species are 450-550 million years removed from the crucial ancestral chain of events. For example, transcript-labelled thin sections of photoreceptor systems in modern amphioxus only speak to the current situation, as does extraction of opsin genes from the new assembly, and speak to the history only by inference. The situation today may be seriously different from the ancestor in terms of both innovations and losses. And that history is not necessarily the most parsimonius (even though we will often assume that).
 
It's worth expanding on this perpetual source of confusion by emphasizing [http://genomewiki.ucsc.edu/index.php/Opsin_evolution:_trichromatic_ancestral_mammal here too] that contemporary tunicates, lancelets, and lamprey are not ancient, ancestral, antiquated, archaic, character-retaining, dead-end, failed experiments, frozen in time, genetically stationary, living fossil, primitive, primordial, relic, or  retro species. They're full modern -- the tree of life is right-justified. Indeed their genes, regulatory signalling systems, and enzymes may be more finely honed than mammals because of more rapid evolution attributable to larger effective population sizes, reproductive mode, generation time, and marine selective predatory pressures.


However we can hope that ancestral character traits will still be reflected to some extent in these earlier diverging species and that with enough complete opsin repertoires from taxonomically appropriate species, the ancestral genes and even visual systems can be reconstructed at key nodes on the phylogenetic tree. The story describing the evolution of the human eye then amounts to describing the status at these successive nodes and perhaps interpolating between them. There are definitely limits to knowledge here as extant metazoans provide only 35 nodes between sponge and human -- gaps between nodes may average 30 million years but can seriously exceed that. This is offset by the occasional proposal of new deuterostome branches (Xenoturbella, Convoluta).
However we can hope that ancestral character traits will still be reflected to some extent in these earlier diverging species and that with enough complete opsin repertoires from taxonomically appropriate species, the ancestral genes and even visual systems can be reconstructed at key nodes on the phylogenetic tree. The story describing the evolution of the human eye then amounts to describing the status at these successive nodes and perhaps interpolating between them. There are definitely limits to knowledge here as extant metazoans provide only 35 nodes between sponge and human -- gaps between nodes may average 30 million years but can seriously exceed that. This is offset by the occasional proposal of new deuterostome branches (Xenoturbella, Convoluta).
Line 22: Line 19:
<tt>Figure adapted from: [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17684563 Acoel Flatworms Are Not Platyhelminthes: Evidence from Phylogenomics] Hervé Philippe et al PLoS ONE. 2007 Aug 8</tt>
<tt>Figure adapted from: [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17684563 Acoel Flatworms Are Not Platyhelminthes: Evidence from Phylogenomics] Hervé Philippe et al PLoS ONE. 2007 Aug 8</tt>


=== <span style="color: #990099;">Callorhinchus (elephantshark) chondrichthyes opsins</span> ===
=== <span style="color: #990099;">Chondrichthyes: Callorhinchus milii (elephantshark) .. 13 opsins</span> ===


Five ray-finned fish genomes are available but these have major lineage-specific expansions and are quite derived. Some sequences are available from lobed-finned fish and coelocanth genome has been proposed. This makes the [http://www.sciencemag.org/cgi/content/full/314/5807/1892 preliminary genome assembly] of the much earlier diverging Callorhinchus (oft-misspelled) and skate transcipts very special because it is the "last stop" before lamprey.  
Five ray-finned fish genomes are available but these have major lineage-specific expansions and are quite derived. Some sequences are available from lobed-finned fish and coelocanth genome has been proposed. This makes the [http://www.sciencemag.org/cgi/content/full/314/5807/1892 preliminary genome assembly] of the much earlier diverging Callorhinchus (oft-misspelled) and skate transcipts very special because it is the "last stop" before lamprey.  
Line 30: Line 27:
I made an exhaustive search of the WGS and Trace divisions of GenBank on 5 Nov 2007, recovering many complete exons but most fragmentary genes. The opsin classifier can easily place these fragments. Overall, Callorhinchus appears to have a full complement of vertebrate opsin genes. The exceptions are RHO2, SWS1, SWS2 (oddly also missing in skate and dogfish ESTs) apparently leaving elephantshark with only RHO1 and LWS rod/cone pigments. Parietopsin was also missing. Two encephalopsin- and two melanopsin-class opsins were found. The RGR, peropsin, and neuropsin genes will prove important in better determining their overall gene tree placement (which an October 2007 [http://www.plosone.org/article/info:doi/10.1371/journal.pone.0001054 opsin phylogeny paper] placed deeply within rhabdopsins).
I made an exhaustive search of the WGS and Trace divisions of GenBank on 5 Nov 2007, recovering many complete exons but most fragmentary genes. The opsin classifier can easily place these fragments. Overall, Callorhinchus appears to have a full complement of vertebrate opsin genes. The exceptions are RHO2, SWS1, SWS2 (oddly also missing in skate and dogfish ESTs) apparently leaving elephantshark with only RHO1 and LWS rod/cone pigments. Parietopsin was also missing. Two encephalopsin- and two melanopsin-class opsins were found. The RGR, peropsin, and neuropsin genes will prove important in better determining their overall gene tree placement (which an October 2007 [http://www.plosone.org/article/info:doi/10.1371/journal.pone.0001054 opsin phylogeny paper] placed deeply within rhabdopsins).


=== <span style="color: #990099;">Petromyzon (lamprey) agnathan opsins</span> ===
=== <span style="color: #990099;">Agnatha: Petromyzon marinus (lamprey) .. 7 opsins</span> ===


Lamprey are the favored outgroup to jawed vertebrates. Geotria and Petromyzon split 280-220 myr ago (helpful in breaking a long branch in half) whereas Lethenteron-Petromyzon was much later 20 myr (unhelpful, too close). Their photoreceptor systems have been studied in [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=AbstractPlus&list_uids=9427550,17463225,15683562,15312025,11774340,9210581,9082962,2776863,2834011 considerable depth].  
Lamprey are the favored outgroup to jawed vertebrates. Geotria and Petromyzon split 280-220 myr ago (helpful in breaking a long branch in half) whereas Lethenteron-Petromyzon was much later 20 myr (unhelpful, too close). Their photoreceptor systems have been studied in [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=AbstractPlus&list_uids=9427550,17463225,15683562,15312025,11774340,9210581,9082962,2776863,2834011 considerable depth].  
Line 40: Line 37:
The high lamprey trace coverage is very helpful to this project. Because most of the opsin sequences are from non-genomic species, the intron structures were not known. I've mapped all GenBank opsin data for Geotria and Lethenteron into Petromyzon using these traces, not only obtaining a nearly full spectrum of new sequences but also sequences parsed for intron breaks and phase. Further, opsin classes not available in other lamprey were collected  using chondrichthyes genes as query. In all cases, intron placement remains perfectly conserved from lamprey to mammal, indeed to amphioxus with some complications. These could help validate orthology candidates in earlier species, especially to clarify the presumably ancient but still cryptic origin of imaging opsins. Intron gain and loss is rare in many lineages -- the vast majority of human introns are conserved back to Urbilatera, indeed to sponge.
The high lamprey trace coverage is very helpful to this project. Because most of the opsin sequences are from non-genomic species, the intron structures were not known. I've mapped all GenBank opsin data for Geotria and Lethenteron into Petromyzon using these traces, not only obtaining a nearly full spectrum of new sequences but also sequences parsed for intron breaks and phase. Further, opsin classes not available in other lamprey were collected  using chondrichthyes genes as query. In all cases, intron placement remains perfectly conserved from lamprey to mammal, indeed to amphioxus with some complications. These could help validate orthology candidates in earlier species, especially to clarify the presumably ancient but still cryptic origin of imaging opsins. Intron gain and loss is rare in many lineages -- the vast majority of human introns are conserved back to Urbilatera, indeed to sponge.


=== <span style="color: #990099;"> Eptatretus (hagfish) agnathan opsins</span> ===
=== <span style="color: #990099;">Agnatha: Eptatretus burgeri (hagfish) .. no opsins yet</span> ===


Hagfish, after decades of back-and-forth, are now [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=AbstractPlus&list_uids=9866205,12927130,17276090,11820840,17301331,1129982,17377535,15288047,7566650,17051155 sistered] with lamprey, news not accepted yet by the Taxonomy division of GenBank. However including rogue taxa such as Oikapleura can severely skew results in molecular phylogeny studies. Monophyly of Cyclostoma is unfortunate if true -- an earlier node would very much help in understanding the origin of the eye. It would be better to put aside tree topology until rare genomic events can be developed and simply procede with opsin sequencing.
Hagfish, after decades of back-and-forth, are now [http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=pubmed&dopt=AbstractPlus&list_uids=9866205,12927130,17276090,11820840,17301331,1129982,17377535,15288047,7566650,17051155 sistered] with lamprey, news not accepted yet by the Taxonomy division of GenBank. However including rogue taxa such as Oikapleura can severely skew results in molecular phylogeny studies. Monophyly of Cyclostoma is unfortunate if true -- an earlier node would very much help in understanding the origin of the eye. It would be better to put aside tree topology until rare genomic events can be developed and simply procede with opsin sequencing.
Line 48: Line 45:
Hagfish are nocturnal in aquaria and deep-sea in their natural habitat -- a new Eptatretus species was even captured at a hydrothermal vent. This lifestyle is not conducive to a well-preserved imaging opsin portfolio, though hagfish still have circadian rhythm (based in the preoptic nucleus) and dermal photoreceptors though no pineal gland.  The non-imaging paired eyes lack cornea, lens, vitreous body, and extrinsic eye muscle but nonetheless the retina and optic nerve react with opsin antibody. The eyes are larger in Eptatretus than in Myxine, where they are partly covered by the trunk musculature. However 1.3 mm is still quite small for an eye. After comparison of all extant genera, Fernholm and Holmberg concluded in 1975 that the hagfish eyes are secondarily degenerated from more conventional eyes adapted for shallow water (for example an early lens placode disappears). The comparative anatomy of hagfish eyes has an excellent discussion in The Biology of Hagfishes (JM Jorgensen), pages 542-543 available by google book search.
Hagfish are nocturnal in aquaria and deep-sea in their natural habitat -- a new Eptatretus species was even captured at a hydrothermal vent. This lifestyle is not conducive to a well-preserved imaging opsin portfolio, though hagfish still have circadian rhythm (based in the preoptic nucleus) and dermal photoreceptors though no pineal gland.  The non-imaging paired eyes lack cornea, lens, vitreous body, and extrinsic eye muscle but nonetheless the retina and optic nerve react with opsin antibody. The eyes are larger in Eptatretus than in Myxine, where they are partly covered by the trunk musculature. However 1.3 mm is still quite small for an eye. After comparison of all extant genera, Fernholm and Holmberg concluded in 1975 that the hagfish eyes are secondarily degenerated from more conventional eyes adapted for shallow water (for example an early lens placode disappears). The comparative anatomy of hagfish eyes has an excellent discussion in The Biology of Hagfishes (JM Jorgensen), pages 542-543 available by google book search.
   
   
No hagfish opsins have been sequenced; no genome project is scheduled. Even if hagfish imaging opsins are mostly gone, other ciliary and rhabdomeric opsins could be quite informative. Hagfish may have information about a critical era in deuterostome imaging opsin evolution.
No hagfish opsins have been sequenced; no genome project is scheduled. Even if hagfish imaging opsins are mostly gone, other ciliary and rhabdomeric opsins could be quite informative. Hagfish may have information about a critical era in deuterostome imaging opsin evolution.


=== <span style="color: #990099;">Stronglyocentrotus (sea urchin) echinoderm opsins</span> ===
=== <span style="color: #990099;">Echinodermata: Stronglyocentrotus purpuratus (sea urchin) .. 6 opsins</span> ===
The sea urchin genome carried a big surprise: the previously dismissed echinoderm has a large set of genes for sensory and signalling capability (comparable in number to human). These include at least [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=16965768,17095691,17067569] six opsins] relevent to our purposes. Adult sea urchins exhibit a variety of responses to light intensity: shelter seeking, covering reactions, diurnal migrations, and spine defense reaction to shadowing. Various pedicellariae (jaw-like appendages around the base of spines) keep the body surface clear of encrusting organisms and aid in food capture. Larva don't have evident eyes but do express an opsin in the post-oral arm suggesting some capabilities..
The sea urchin genome carried a big surprise: the previously dismissed echinoderm has a large set of genes for sensory and signalling capability (comparable in number to human). These include at least [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=16965768,17095691,17067569] six opsins] relevent to our purposes. Adult sea urchins exhibit a variety of responses to light intensity: shelter seeking, covering reactions, diurnal migrations, and spine defense reaction to shadowing. Various pedicellariae (jaw-like appendages around the base of spines) keep the body surface clear of encrusting organisms and aid in food capture. Larva don't have evident eyes but do express an opsin in the post-oral arm suggesting some capabilities..
   
   
Line 65: Line 62:
The two remaining opsins classify as rhadomeric melanopsins. One of them, MEL2_strPur, has a GenBank transcript DQ285097 alluding to an unpublished expression study concerning tube feet photoreceptors. The other melanopsin is expressed post-oral arm of two-week-old larvae.
The two remaining opsins classify as rhadomeric melanopsins. One of them, MEL2_strPur, has a GenBank transcript DQ285097 alluding to an unpublished expression study concerning tube feet photoreceptors. The other melanopsin is expressed post-oral arm of two-week-old larvae.


=== <span style="color: #990099;">Saccoglossus (acornworm) hemichordate opsins</span> ===
=== <span style="color: #990099;">Hemichordata: Saccoglossus kowalevskii (acornworm) .. 1 opsin</span> ===
This surviving member of early branching deuterostomes has excellent genomic and trancript coverage, with diverse full length multi-exon genes often recoverable. Be aware that transcript data has been <span style="color: #990099;">misplaced</span> by GenBank to reside under Saccloglossus 'other' at the trace archives. However acorn worm may not illuminate photoreception at its ancestral node with echinoderms (Ambulacraria). Acornworm have isolated photoreceptive cells are [http://webs.lander.edu/rsfox/invertebrates/saccoglossus.html scattered through the epidermis] but no eyes or eye spots even as [http://adsabs.harvard.edu/abs/1952RSPTB.236..553B planktonic larva], as befits an animal that settles in its burrow on day two. Light striking epidermal photoreceptors elicits burrowing behavior.
This surviving member of early branching deuterostomes has excellent genomic and trancript coverage, with diverse full length multi-exon genes often recoverable. Be aware that transcript data has been <span style="color: #990099;">misplaced</span> by GenBank to reside under Saccloglossus 'other' at the trace archives. However acorn worm may not illuminate photoreception at its ancestral node with echinoderms (Ambulacraria). Acornworm have isolated photoreceptive cells are [http://webs.lander.edu/rsfox/invertebrates/saccoglossus.html scattered through the epidermis] but no eyes or eye spots even as [http://adsabs.harvard.edu/abs/1952RSPTB.236..553B planktonic larva], as befits an animal that settles in its burrow on day two. Light striking epidermal photoreceptors elicits burrowing behavior.


Line 78: Line 75:
</pre>
</pre>


=== <span style="color: #990099;">Xenoturbella plus Convoluta no opsins yet</span> ===
=== <span style="color: #990099;">Deuterostomia: Xenoturbella bocki + Convoluta pulchra .. 0 opsins</span> ===
These two taxa have recently been put forward as new phyla of basal deuterostomes, the former as [http://www.ncbi.nlm.nih.gov/sites/entrez?cmd=retrieve&db=pubmed&dopt=AbstractPlus&list_uids=16495997 outgroup] to echinoderms plus hemichordates, the latter acoel flatworms as [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17684563 more basal still]. However sequence data is extremely sparse with 3,127 sequences for all of Acoelomorpha, and Convoluta pulchra evolving far too fast for practical use, with its tree position [http://www.ncbi.nlm.nih.gov/sites/entrez?cmd=retrieve&db=pubmed&dopt=AbstractPlus&list_uids=15382134,10082465 controversial].
These two taxa have recently been put forward as new phyla of basal deuterostomes, the former as [http://www.ncbi.nlm.nih.gov/sites/entrez?cmd=retrieve&db=pubmed&dopt=AbstractPlus&list_uids=16495997 outgroup] to echinoderms plus hemichordates, the latter acoel flatworms as [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17684563 more basal still]. However sequence data is extremely sparse with 3,127 sequences for all of Acoelomorpha, and Convoluta pulchra evolving far too fast for practical use, with its tree position [http://www.ncbi.nlm.nih.gov/sites/entrez?cmd=retrieve&db=pubmed&dopt=AbstractPlus&list_uids=15382134,10082465 controversial].


No genome or major transcript studies are under consideration. A quick check via tblastn of sea urchin opsins against available transcripts does not turn up good opsin candidates as of 28 Nov 2007 (other than a weak melanopsin match in Convoluta, EV602614, that might instead be generic GPCR). No information about photoreception in these species is readily available. While the above two taxa might not be ideal for opsin purposes, extant species are very limited.
No genome or major transcript studies are under consideration. A quick check via tblastn of sea urchin opsins against available transcripts does not turn up good opsin candidates as of 28 Nov 2007 (other than a weak melanopsin match in Convoluta, EV602614, that might instead be generic GPCR). No information about photoreception in these species is readily available. While the above two taxa might not be ideal for opsin purposes, extant species are very limited.


=== <span style="color: #990099;">Platynereis (polychaete) lophotrochozoa opsins</span> ===
=== <span style="color: #990099;">Lophotrochozoa: Platynereis dumerilii (polychaete) .. 3 opsins</span> ===


This small annelid may be an emerging model organism, though plans for genome sequencing in France have apparently collapsed. (Indeed all metazoan genomic sequencing in Europe has ceased.), Three [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=16311335,15514158,11874910 recent papers] have established that Platynereis qualifies as living fossil, at least with respect to ancestral anatomy and development, slowly evolving protein sequences and retention of genes and ancestral introns, and further has retained ciliary opsins.  
This small annelid may be an emerging model organism, though plans for genome sequencing in France have apparently collapsed. (Indeed all metazoan genomic sequencing in Europe has ceased.), Three [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=16311335,15514158,11874910 recent papers] have established that Platynereis qualifies as living fossil, at least with respect to ancestral anatomy and development, slowly evolving protein sequences and retention of genes and ancestral introns, and further has retained ciliary opsins.  
Line 102: Line 99:
That's a striking coincidence in that antibody to acetylated alpha-tubulin was used as marker for stabilized microtubules in cilia and axons -- almost close enough for coupled expression especially when that contig piece is flipped (reverse complemented so that all the opsin exons are on the same strand). That brings the intergene distance to 8200 bp (end of opsin 53730 - start of tubulin 61901). That's something to keep in mind in terms of establishing syntenic orthologs in other lophotrochozoa.
That's a striking coincidence in that antibody to acetylated alpha-tubulin was used as marker for stabilized microtubules in cilia and axons -- almost close enough for coupled expression especially when that contig piece is flipped (reverse complemented so that all the opsin exons are on the same strand). That brings the intergene distance to 8200 bp (end of opsin 53730 - start of tubulin 61901). That's something to keep in mind in terms of establishing syntenic orthologs in other lophotrochozoa.


=== <span style="color: #990099;">Hypsibius (water bear) tardigrade no opsins yet</span> ===
=== <span style="color: #990099;">Tardigrada: Hypsibius dujardini (water bear) tardigrade 0 opsins</span> ===


A  5x genome project for Hypsibius dujardini, a phylum of microscopic ecdysozoan was approved in July 2007 but Broad has not yet begun trace reads on the small 70 mbp genome (suggesting densely spaced genes with small introns as this is not likely highly derived). It could prove very useful for opsins as [http://www.genome.gov/Pages/Research/Sequencing/SeqProposals/EcdysozoaProposalFinalPDF.pdf tardigrades] are basal to all of Arthropoda and so shed light on that last common ancester. In fact with accompanying centipede, horseshoe crab, amphipod, and priapulid genomes, the whole ecdysozoan ancester will be accessible.  
A  5x genome project for Hypsibius dujardini, a phylum of microscopic ecdysozoan was approved in July 2007 but Broad has not yet begun trace reads on the small 70 mbp genome (suggesting densely spaced genes with small introns as this is not likely highly derived). It could prove very useful for opsins as [http://www.genome.gov/Pages/Research/Sequencing/SeqProposals/EcdysozoaProposalFinalPDF.pdf tardigrades] are basal to all of Arthropoda and so shed light on that last common ancester. In fact with accompanying centipede, horseshoe crab, amphipod, and priapulid genomes, the whole ecdysozoan ancester will be accessible.  
Line 113: Line 110:




=== <span style="color: #990099;">Ixodes (tick)</span> ===
=== <span style="color: #990099;">Chelicerata: Ixodes scapularis (tick) 1 opsin</span> ===


The genome project was completed long ago but has experienced a multi-year bottleneck in assembly release and publication. However contigs built from 19.4 million traces should become available to tblastn of the GenBank "wgs" division by late 2007. Ixodes has a very conservative genome (regretably 2.1 gbp in size), seemingly far less derived than drosophilids in matters such as intron, gene retention,  and protein sequence conservation. This, in conjunction with the helpful phylogenetic position of chelicerate outgroup to the many insect genomes, has improved prospects for reconstructing the ancestal opsin repertoire of Arthropoda and eventually Protostomia and UrBilatera.
The genome project was completed long ago but has experienced a multi-year bottleneck in assembly release and publication. However contigs built from 19.4 million traces should become available to tblastn of the GenBank "wgs" division by late 2007. Ixodes has a very conservative genome (regretably 2.1 gbp in size), seemingly far less derived than drosophilids in matters such as intron, gene retention,  and protein sequence conservation. This, in conjunction with the helpful phylogenetic position of chelicerate outgroup to the many insect genomes, has improved prospects for reconstructing the ancestal opsin repertoire of Arthropoda and eventually Protostomia and UrBilatera.
Line 119: Line 116:
A large collection of annotated Ixodes ESTs is available at the [http://compbio.dfci.harvard.edu/tgi/cgi-bin/tgi/gireport.pl?gudb=i_scapularis DFCI Gene Index] of which 3 are marked up (2 wrongly) as opsins. Using the [http://genomewiki.ucsc.edu/index.php/Opsin_evolution Opsin Classifier], I recovered the full length gene for the first of these TC19272 on 24 Nov 07, intronated the transcript at the Trace Archives (4 introns, superb coverage), and added it to the [http://genomewiki.ucsc.edu/index.php/Opsin_evolution classifier fasta collection] as RHAB1_ixoSca. It classifies with rhabdomeric opsins (ie with deuterostome melanopsins) with a very respectable 57% maximal percent protein identity. The second and third intron have classical ancestral position (following GWSR and LAK) and phase (2 and 0). Synteny awaits assembly of large contigs -- adjacent exons are not spanned by single traces. An apparent ciliary opsin fragment in Ixodes was located using that of Platynereis dumerilii as probe, it is stored as CILI_ixoSca but needs further analysis.
A large collection of annotated Ixodes ESTs is available at the [http://compbio.dfci.harvard.edu/tgi/cgi-bin/tgi/gireport.pl?gudb=i_scapularis DFCI Gene Index] of which 3 are marked up (2 wrongly) as opsins. Using the [http://genomewiki.ucsc.edu/index.php/Opsin_evolution Opsin Classifier], I recovered the full length gene for the first of these TC19272 on 24 Nov 07, intronated the transcript at the Trace Archives (4 introns, superb coverage), and added it to the [http://genomewiki.ucsc.edu/index.php/Opsin_evolution classifier fasta collection] as RHAB1_ixoSca. It classifies with rhabdomeric opsins (ie with deuterostome melanopsins) with a very respectable 57% maximal percent protein identity. The second and third intron have classical ancestral position (following GWSR and LAK) and phase (2 and 0). Synteny awaits assembly of large contigs -- adjacent exons are not spanned by single traces. An apparent ciliary opsin fragment in Ixodes was located using that of Platynereis dumerilii as probe, it is stored as CILI_ixoSca but needs further analysis.


=== <span style="color: #990099;">Daphnia (water flea)</span> ===
=== <span style="color: #990099;">Crustacea: Daphnia pulex (water flea) .. 37 opsins</span> ===


An 8.7x genome assembly was released in July 2007 at [http://www.jgi.doe.gov/Daphnia/ JGI] with further support at [http://wfleabase.org/ wFleaBase]. This crustacean provides a potentially [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17612412 important outgroup] to insects (together forming Pancrustacea). However the opsin story, summarized in a [https://dgc.cgb.indiana.edu/display/daphnia/Carla+Caceres meeting abstract] is an embarrassment of riches, not conducive to deducing ancestral arthropod genome content. The total number of opsin genes came in at 37, comprised of 22 rhabdomeric opsins (mostly long wavelength), 7 ciliary opsins (pteropsins), and 8 in a novel family without close affiliates. This seems excessive but Daphnia has ommatidia (compound eyes), circadian rhythms, and a need to assess water turbidity and depth. Planned in situ hybridization studies may illuminate biological roles of these opsins. The pteropsins are probably of most interest here.
An 8.7x genome assembly was released in July 2007 at [http://www.jgi.doe.gov/Daphnia/ JGI] with further support at [http://wfleabase.org/ wFleaBase]. This crustacean provides a potentially [http://www.pubmedcentral.nih.gov/articlerender.fcgi?tool=pubmed&pubmedid=17612412 important outgroup] to insects (together forming Pancrustacea). However the opsin story, summarized in a [https://dgc.cgb.indiana.edu/display/daphnia/Carla+Caceres meeting abstract] is an embarrassment of riches, not conducive to deducing ancestral arthropod genome content. The total number of opsin genes came in at 37, comprised of 22 rhabdomeric opsins (mostly long wavelength), 7 ciliary opsins (pteropsins), and 8 in a novel family without close affiliates. This seems excessive but Daphnia has ommatidia (compound eyes), circadian rhythms, and a need to assess water turbidity and depth. Planned in situ hybridization studies may illuminate biological roles of these opsins. The pteropsins are probably of most interest here.
Line 131: Line 128:
The synteny circle surviving at this phylogenetic depth will be local (optimistically Pancrustacean). That is, the blue opsin of Daphnia might in synteny with Drosophila (ie establish orthology) but not to Platynereis ciliary opsin much less any vertebrate opsin (eg encephalopsin). This could be remedied to some extent by ancestral gene order reconstruction. The degree to which synteny can contribute to validating orthology relations within opsins is not currently known.
The synteny circle surviving at this phylogenetic depth will be local (optimistically Pancrustacean). That is, the blue opsin of Daphnia might in synteny with Drosophila (ie establish orthology) but not to Platynereis ciliary opsin much less any vertebrate opsin (eg encephalopsin). This could be remedied to some extent by ancestral gene order reconstruction. The degree to which synteny can contribute to validating orthology relations within opsins is not currently known.


=== <span style="color: #990099;">Carybdea marsupialis (jellyfish) cnidarian no opsins yet</span> ===
=== <span style="color: #990099;">Cnidaria: Carybdea marsupialis (jellyfish) cnidarian .. 0 opsins</span> ===
Cnidarians are the earliest diverging invertebrates with multicellular light-detecting organs, called ocelli. Photodetectors include simple eyespots, pigment cups, complex pigment cups with lenses, and camera-type eyes with a cornea, lens, and retina. These remarkable eyes are located on sensory clubs called rhopalia with four lining the bell of Each houses six eyes: a pair of pit ocelli, a pair of slit ocelli, and two unpaired lens eyes with counterparts to cornea, cellular lens and retina of ciliated photoreceptors. Anatomically, ocelli have bipolar sensory photoreceptor cells interspersed among nonsensory pigment cells with the apical end making the light-receptor and the basal end forming an axon that synapses with second-order neurons to form what amounts to ocular nerves.   
Cnidarians are the earliest diverging invertebrates with multicellular light-detecting organs, called ocelli. Photodetectors include simple eyespots, pigment cups, complex pigment cups with lenses, and camera-type eyes with a cornea, lens, and retina. These remarkable eyes are located on sensory clubs called rhopalia with four lining the bell of Each houses six eyes: a pair of pit ocelli, a pair of slit ocelli, and two unpaired lens eyes with counterparts to cornea, cellular lens and retina of ciliated photoreceptors. Anatomically, ocelli have bipolar sensory photoreceptor cells interspersed among nonsensory pigment cells with the apical end making the light-receptor and the basal end forming an axon that synapses with second-order neurons to form what amounts to ocular nerves.   


Line 140: Line 137:
Vision has roles in the reproduction and feeding of cubomedusae which can find each other and chase, catch, and eat teleost fish. A patch of Pelagia nocticula 10 square miles in extent and 35 feet deep recently destroyed a salmon farm off Northern Ireland.
Vision has roles in the reproduction and feeding of cubomedusae which can find each other and chase, catch, and eat teleost fish. A patch of Pelagia nocticula 10 square miles in extent and 35 feet deep recently destroyed a salmon farm off Northern Ireland.


=== <span style="color: #990099;">Amphimedon (sponge) and earlier metazoan lack opsins</span> ===
=== <span style="color: #990099;">Porifera: Amphimedon queenslandica (sponge) and earlier metazoan lack opsins</span> ===
Sponges lie at the base of multicellular animals. They are not noted for eyes. However demosponge larva do exhibit phototaxis (shadow seeking under coral rubble) but the action spectrum is [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=11976887 reportedly] a better fit to a flavin or carotenoid chromophore. The genome of Amphimedon queenslandica has been available for years at the Trace Archives but never assembled. The species was formerly called Reniera spp. and it is still carried under that name at [http://www.jgi.doe.gov/sequencing/why/CSP2005/reniera.html JGI Genome]. Consequently tblastn of contigs is not available without do-it-yourself assembly.  
Sponges lie at the base of multicellular animals. They are not noted for eyes. However demosponge larva do exhibit phototaxis (shadow seeking under coral rubble) but the action spectrum is [http://www.pubmedcentral.nih.gov/articlerender.fcgi?artid=11976887 reportedly] a better fit to a flavin or carotenoid chromophore. The genome of Amphimedon queenslandica has been available for years at the Trace Archives but never assembled. The species was formerly called Reniera spp. and it is still carried under that name at [http://www.jgi.doe.gov/sequencing/why/CSP2005/reniera.html JGI Genome]. Consequently tblastn of contigs is not available without do-it-yourself assembly.  


Line 149: Line 146:
=== Coming real soon! ===
=== Coming real soon! ===


==== <span style="color: #990099;">Ciona (tunicate) urochordate opsins</span> ====
==== <span style="color: #990099;">Urochordata: Ciona intestinalis (tunicate) .. 2 opsins</span> ====


==== <span style="color: #990099;">Branchiostoma (amphioxus) cephalochordate opsins</span> ====
==== <span style="color: #990099;">Cephalochordata: Branchiostoma (amphioxus) .. 7 opsins</span> ====


==== <span style="color: #990099;">Schmidtea (planaria) opsins</span> ====
==== <span style="color: #990099;">Platyhelminthes: Schmidtea mediterranea (planaria) .. 1 opsin</span> ====


==== <span style="color: #990099;">Capitella (annelid) lophotrochozoan opsins</span> ====
==== <span style="color: #990099;">Lophotrochozoa: Capitella sp (annelid) .. 0 opsins</span> ====


==== <span style="color: #990099;">Lottia and Aplysia lophotrochozoan opsins</span> ====
==== <span style="color: #990099;">Lophotrochozoa: Lottia gigantea (limpet) + Aplysia californica (sea hare).. 0 opsins</span> ====


==== <span style="color: #990099;">Nematostella (anemone) cnidarian  opsins</span> ====
==== <span style="color: #990099;">Cnidaria: Nematostella stellata (anemone) .. 4 opsins</span> ====


==== <span style="color: #990099;">Hydra (hydra) cnidarian opsins</span> ====
==== <span style="color: #990099;">Cnidaria: Hydra magnipapillata (hydra) .. 2 opsins</span> ====




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

Revision as of 15:36, 30 November 2007

Key Critters

Some species such as drosophila have lost all ciliary opsins -- clearly they are not essential for a successful visually complex flying insect with 5-color vision and circadian rhythm. Bees, annelids, and mammals retain ciliary opsins so we know this must be the ancestral bilateran state state. This predicts ciliary opsins in cnidaria and indeed one was just found in cnidaria. One sees the importance of complete genomes here (versus transcripts or immunostained sections): absence of ciliary opsin evidence in a genome is truly evidence of ciliary opsin absence.

When the eye is reduced to a single pigment cell backing a single photoreceptor cell, the opsin of that species will be expressed only in one cell of the entire body. In this situation, the opsin may never show up in transcript collections, even with subtraction of common ones.

Vertebrates could never have evolved cilliary opsin vision had the bilateran ancestor possessed the limited opsin repertoire of fruit fly. Thus most pressing question is -- assuming rhabdomeric opsins were thoroughly entrenched in the earliest imaging eyes and photoreception systems -- what kept ciliary opsins around in early bilatera (and even cnidaria) so that they could later be co-opted for ciliary opsin-based vision? We ttp://genomewiki.ucsc.edu/index.php/Opsin_evolution:_trichromatic_ancestral_mammal here too] that contemporary tunicates, lancelets, and lamprey are not ancient, ancestral, antiquated, archaic, character-retaining, dead-end, failed experiments, frozen in time, genetically stationary, living fossil, primitive, primordial, relic, or retro species. They're full modern -- the tree of life is right-justified. Indeed their genes, regulatory signalling systems, and enzymes may be more finely honed than mammals because of more rapid evolution attributable to larger effective population sizes, reproductive mode, generation time, and marine selective predatory pressures.

However we can hope that ancestral character traits will still be reflected to some extent in these earlier diverging species and that with enough complete opsin repertoires from taxonomically appropriate species, the ancestral genes and even visual systems can be reconstructed at key nodes on the phylogenetic tree. The story describing the evolution of the human eye then amounts to describing the status at these successive nodes and perhaps interpolating between them. There are definitely limits to knowledge here as extant metazoans provide only 35 nodes between sponge and human -- gaps between nodes may average 30 million years but can seriously exceed that. This is offset by the occasional proposal of new deuterostome branches (Xenoturbella, Convoluta).

The ideal set of genomes needed to study the evolution of the metazoan eye is only partly completed, underway, or even proposed. In some cases, the genome size of clade representatives is so large (eg lungfish at 25x human) the species may never be sequenced, though opsin transcripts could still be obtained. In others, the rate of evolution has been so fast so long that very little information about photoreception at ancestral nodes can remain (eg Oikopleura). Hagfish opsins, which would conveniently break up the crucial lamprey long branch, are not available at GenBank but here the animal has adopted a deep water (dark) habitat, meaning that its cone opsin genomic repertoire will be highly reduced, if not gone entirely, in its markedly degenerated eyes. (Its other opsins could still be informative.)

Model organism choices do not always coincide with genome sequenceability, transcriptome projects, nor (worst of all) with slow-evolving less derived species. Finally, most sequencing speaks to narrow anthropocentric interests, whereas the more broadly conceived sequencing need is greatest farther back (to break up branches). The evolution of the eye needs a rather different portfolio of genomes than a typical disease gene because of the earlier intrinsic timing of the innovative events. In fact, one product of the investigation here is to spell out these needed genomes. Of course one obvious genome choice is the cubomedusan jellyfish Carybdea marsupialis with its 24 eyes of 6 types.

It's worth reviewing genome status and recent experimental literature on key species. While abstracts are readily available at PubMed, access to free full text is unpredictable, so those links are collected when available. It suffice to reference only recent articles because they cite the earlier literature and citation in turn of their paper are collected by Google Scholar (or AbstractsPlus at PubMed). Most opsin sequences in the Opsin evolution reference sequence collection have a PubMed accession as a field their fasta header database; those can simply be compiled to an active link that opens all of them in one PubMed window.

OpsineyePhylo.png

Figure adapted from: Acoel Flatworms Are Not Platyhelminthes: Evidence from Phylogenomics Hervé Philippe et al PLoS ONE. 2007 Aug 8

Chondrichthyes: Callorhinchus milii (elephantshark) .. 13 opsins

Five ray-finned fish genomes are available but these have major lineage-specific expansions and are quite derived. Some sequences are available from lobed-finned fish and coelocanth genome has been proposed. This makes the preliminary genome assembly of the much earlier diverging Callorhinchus (oft-misspelled) and skate transcipts very special because it is the "last stop" before lamprey.

This large-eyed cartilaginous fish lives to depths to 200m on the continental shelf of southern Australia and New Zealand but migrates into coastal estuaries to lay egg cases (lower image) in sand and muddy substrates. The distinctively-shaped egg cases are sometimes found washed ashore after storms. They are up to 25cm long, 10cm wide, and take up to eight months to hatch. The one studied member of the genus has a vitamin A1-based photopigment with maximum absorbance at 499 nm presumably adapted to its overall photic environment.

I made an exhaustive search of the WGS and Trace divisions of GenBank on 5 Nov 2007, recovering many complete exons but most fragmentary genes. The opsin classifier can easily place these fragments. Overall, Callorhinchus appears to have a full complement of vertebrate opsin genes. The exceptions are RHO2, SWS1, SWS2 (oddly also missing in skate and dogfish ESTs) apparently leaving elephantshark with only RHO1 and LWS rod/cone pigments. Parietopsin was also missing. Two encephalopsin- and two melanopsin-class opsins were found. The RGR, peropsin, and neuropsin genes will prove important in better determining their overall gene tree placement (which an October 2007 opsin phylogeny paper placed deeply within rhabdopsins).

Agnatha: Petromyzon marinus (lamprey) .. 7 opsins

Lamprey are the favored outgroup to jawed vertebrates. Geotria and Petromyzon split 280-220 myr ago (helpful in breaking a long branch in half) whereas Lethenteron-Petromyzon was much later 20 myr (unhelpful, too close). Their photoreceptor systems have been studied in considerable depth.

Geotria australis has a full complement of imaging opsins LWS, SWS1, SWS2, RHO2, and RHO1 as well as the other major opsin classes. This implies that the ancestral vertebrate possessed photopic (bright light) cone-based vision with the potential for pentachromacy, circadian rhythm, pupilary reflex, and pineal and parapineal functions. Photoreceptor morphology and spectral sensitivity can change during various phases of the lamprey lifecycle, a lineage-specific complication that does not concern us.

The lamprey genome project has stalled, despite accruing an impressive 19 million traces. It seems a 16 kbp retroposon has expanded enormously, making assembly all but impossible. However new sequencing technologies make an immense collection of cDNA affordable. This would permit a pseudo-assembly of exons flanked by some at least genomic dna. That is, transcripts are aligned into the trace archives to obtain non-coding context for exons. This allows some topics to be studied (intron retention, invariant non-coding) but not others (upstream regulatory, chromosomal gene order). Labelling techniques such as FISH could provide some linkages but not gene-level order; perhaps this could be done at the level of BACs using exons from all possible gene pairs. Alternatively, the genome of Geotria might present fewer issues.

The high lamprey trace coverage is very helpful to this project. Because most of the opsin sequences are from non-genomic species, the intron structures were not known. I've mapped all GenBank opsin data for Geotria and Lethenteron into Petromyzon using these traces, not only obtaining a nearly full spectrum of new sequences but also sequences parsed for intron breaks and phase. Further, opsin classes not available in other lamprey were collected using chondrichthyes genes as query. In all cases, intron placement remains perfectly conserved from lamprey to mammal, indeed to amphioxus with some complications. These could help validate orthology candidates in earlier species, especially to clarify the presumably ancient but still cryptic origin of imaging opsins. Intron gain and loss is rare in many lineages -- the vast majority of human introns are conserved back to Urbilatera, indeed to sponge.

Agnatha: Eptatretus burgeri (hagfish) .. no opsins yet

Hagfish, after decades of back-and-forth, are now sistered with lamprey, news not accepted yet by the Taxonomy division of GenBank. However including rogue taxa such as Oikapleura can severely skew results in molecular phylogeny studies. Monophyly of Cyclostoma is unfortunate if true -- an earlier node would very much help in understanding the origin of the eye. It would be better to put aside tree topology until rare genomic events can be developed and simply procede with opsin sequencing.

Jawless fish first appeared in the Ordovician. Hagfish and lamprey split well after the Cambrian, roughly 430 myr ago according to molecular clocks. That's a time span comparable to divergence of human from shark. The oldest fossil hagfishes are Late Carboniferous (330 myr). The two extant hagfish groups split some 75 myr ago (human from mouse). Only recently has it been possible to obtain hagfish eggs and embryos and revisit the neural crest issue. Hagfish experienced an extra round of HOX gene expansion, undercutting both HOX cluster copy number as a hallmark of supposed vertebrate body plan innovation and premature speculation on 1R and 2R whole genome duplication.

Hagfish are nocturnal in aquaria and deep-sea in their natural habitat -- a new Eptatretus species was even captured at a hydrothermal vent. This lifestyle is not conducive to a well-preserved imaging opsin portfolio, though hagfish still have circadian rhythm (based in the preoptic nucleus) and dermal photoreceptors though no pineal gland. The non-imaging paired eyes lack cornea, lens, vitreous body, and extrinsic eye muscle but nonetheless the retina and optic nerve react with opsin antibody. The eyes are larger in Eptatretus than in Myxine, where they are partly covered by the trunk musculature. However 1.3 mm is still quite small for an eye. After comparison of all extant genera, Fernholm and Holmberg concluded in 1975 that the hagfish eyes are secondarily degenerated from more conventional eyes adapted for shallow water (for example an early lens placode disappears). The comparative anatomy of hagfish eyes has an excellent discussion in The Biology of Hagfishes (JM Jorgensen), pages 542-543 available by google book search.

No hagfish opsins have been sequenced; no genome project is scheduled. Even if hagfish imaging opsins are mostly gone, other ciliary and rhabdomeric opsins could be quite informative. Hagfish may have information about a critical era in deuterostome imaging opsin evolution.

Echinodermata: Stronglyocentrotus purpuratus (sea urchin) .. 6 opsins

The sea urchin genome carried a big surprise: the previously dismissed echinoderm has a large set of genes for sensory and signalling capability (comparable in number to human). These include at least [1] six opsins] relevent to our purposes. Adult sea urchins exhibit a variety of responses to light intensity: shelter seeking, covering reactions, diurnal migrations, and spine defense reaction to shadowing. Various pedicellariae (jaw-like appendages around the base of spines) keep the body surface clear of encrusting organisms and aid in food capture. Larva don't have evident eyes but do express an opsin in the post-oral arm suggesting some capabilities..

Opsin urchin expr.png

Because sea urchins are seriously diverged, it is difficult to recover accurate full-length sequences by homology, especially in poorly conserved termini, without transcript evidence. At this point, only one of six urchin opsins has any cdna support -- and that from a different species of urchin! That melanopsin interestingly consists of a single exon -- evidently retroposed but still functional -- for which no parent gene can be located. It is not unusual for a descendent gene to supplant the multi-exonic parent, perhaps by accident, perhaps because of transcriptional efficiency considerations.

The two peropsin-class Go urchin sequences are adjacent in parallel tandem configuration with identical intron pattern but have only 64% amino acid identity, consistent with a moderately old tandem duplication. Despite additional weak members of this group, care must be taken not to drift off-topic into the greater rhodopsin superfamily of GPCRs (979 genes in 70 families annotated in urchin).

The sea urchin genome contains one very clear ciliary opsin (called PIN_stoPur in the sequence storage area). Here the GLEAN3_05569 prediction from Baylor appears entirely accurate whereas GenScan and GNOMON XM_778209 and XM_001177470 are impossibly flawed. The Opsin Classifier classifies this somewhat ambiguously within pinopsin-encephalopsin, suggesting it might seed a new ciliary opsin class. The intron pattern 0.2.2.0.0 is a perfect match in position and phase to pinopsins. Indels will be considered when the global alignment is revisited. It has no detectable counterpart in the Saccoglossus genome.

There appears to be a second ciliary opsin (stored as ENCEPH_strPur). It is best fit to Branchiostoma and Platynereis ciliary opsins but only at 33% identity and not that distant to certain melanopsins. This opsin too is likely to be involved in some aspect of photoreception, though that won't be as closely related to vertebrate imaging as PIN_stoPur.

The two remaining opsins classify as rhadomeric melanopsins. One of them, MEL2_strPur, has a GenBank transcript DQ285097 alluding to an unpublished expression study concerning tube feet photoreceptors. The other melanopsin is expressed post-oral arm of two-week-old larvae.

Hemichordata: Saccoglossus kowalevskii (acornworm) .. 1 opsin

This surviving member of early branching deuterostomes has excellent genomic and trancript coverage, with diverse full length multi-exon genes often recoverable. Be aware that transcript data has been misplaced by GenBank to reside under Saccloglossus 'other' at the trace archives. However acorn worm may not illuminate photoreception at its ancestral node with echinoderms (Ambulacraria). Acornworm have isolated photoreceptive cells are scattered through the epidermis but no eyes or eye spots even as planktonic larva, as befits an animal that settles in its burrow on day two. Light striking epidermal photoreceptors elicits burrowing behavior.

In searching for opsins that might underlie epidermal (or other) photoreception, the best queries (for detecting diverged sequences) are likely sea urchin opsins against Saccloglossus 'other' because, being transcripts rather than short exons, these give longer matches. However opsins expressed in scattered cells may not be represented there if rarely transcibed. Promising traces must be back-blastxed against the Opsin Classifier because the initial query choice may have beeen sub-optimal. Good matches can then be intronated using the exact-matching Saccoglossus probe against genomic reads. Intron patterns are critical adjuncts to low sequence alignments in establishing opsin orthology classes because surviving synteny at this time depth is rare.

I report here the very first hemichordate opsin. The process for obtaining accurate gene models in such a remote species is a difficult exercise in bioinformatics and use of the Opsin Classifier -- a detailed procedure is given in a separate note. That Saccoglossus opsin classifies unambiguously to the peropsin/neuropsin group by similarity and intron structure and thus is not a strong candidate for the epidermal photoreceptor -- but it suggests the story is not that simple. A complete set of opsins for these species best awaits release of assembled contigs by the Baylor sequencing center.

>PER_sacKol Saccoglossus kowalevskii Expect = 2.0e-49 PERa_braFlo Identities = 97/246 (39%)
IIYYFFLLSTGLTIFGMSLSCVSSF GRWLFGKFGCYFHGFAGMLFGLGSIGNLTVISIDRYIITCKRSL 1
2 WSYRHYYALLAVAWSNALFWSMMPLFGWSSYALEPEGTSCTIDWMNNDNQYISYVSCVTVTCFILPCAVMTYDYLAAYMKMVKAGYTLSEETEKPNND 0
0 MCIALVAAFLLSWFPSATVFLWAAFGNPGNIPLSFTGVADAFTKIPAVFNPVIYVALNPEFRKYFGKTIGCRRKRKKPIAVRLNGSEQNVENTI* 0

Deuterostomia: Xenoturbella bocki + Convoluta pulchra .. 0 opsins

These two taxa have recently been put forward as new phyla of basal deuterostomes, the former as outgroup to echinoderms plus hemichordates, the latter acoel flatworms as more basal still. However sequence data is extremely sparse with 3,127 sequences for all of Acoelomorpha, and Convoluta pulchra evolving far too fast for practical use, with its tree position controversial.

No genome or major transcript studies are under consideration. A quick check via tblastn of sea urchin opsins against available transcripts does not turn up good opsin candidates as of 28 Nov 2007 (other than a weak melanopsin match in Convoluta, EV602614, that might instead be generic GPCR). No information about photoreception in these species is readily available. While the above two taxa might not be ideal for opsin purposes, extant species are very limited.

Lophotrochozoa: Platynereis dumerilii (polychaete) .. 3 opsins

This small annelid may be an emerging model organism, though plans for genome sequencing in France have apparently collapsed. (Indeed all metazoan genomic sequencing in Europe has ceased.), Three recent papers have established that Platynereis qualifies as living fossil, at least with respect to ancestral anatomy and development, slowly evolving protein sequences and retention of genes and ancestral introns, and further has retained ciliary opsins.

That is to say, fruit fly and nematode have proven unfortunate choices because of so many lost genes and signalling pathways, rapid evolution and highly derived characters. Lophotrochozoa may thus give us very significant insight into the bilateran ancestor that had appeared lost from consideration of just Arthropoda. It should be noted though that not all insects should be written off, Anopheles has also retained ciliary opsins.

Platynereis develops various pairs of eyes going by opsin expression: inverse larval eyes used in phototaxis (just one pigment cell and one photoreceptor cell) and two pairs of everse adult eyes needed for adult vision. These originate from an initially unsplit single anlage. These eyes use exclusively rhabdomeric photoreceptor cells and corresponding rhabdomeric-class opsins as expected from phylogenetic position. However two paired structures in the developing median brain dorsal to the apical organ express an opsin that unambiguously classifies as ciliary. Further, a retinal homeobox (specific to ciliary pineal eyes) and circadian rhythm regulator bmal are also expressed at this location in Platynereis. However the pigment cells necessary for directional photoreception are missing. This all fits with a role for the ciliary opsin as the primary receptor underlying circadian rhythm.

The emerging picture is Ur-Bilatera having both ciliary and rhabdomeric structure. The later structure was lost but the photoreceptor component retained in vertebrates in the form of melanopsins in retinal ganglion cells.


Opsin parallels.png

Opsin everse.png



Remarkably using the transcript ciliary opsin as probe on a 171,779 bp forgotten high throughput genomic sequence CT030681, I found a second ciliary opsin fragment with encephalopsin character which could be intronated (unlike the original). This needs confirmation of its signalling partner through study of diagnostic binding residues. One of the exons lies on the minus strand suggesting partial assembly of the 6 unordered contig pieces. (These are stored in the Opsin Classifier as CILL1_plaDum and CILL2_plaDum, resp.). The only other apparent coding gene on this contig (blastx vs metazoan proteins) is alpha-tubulin, positions 124517-122811, downstream from the second ciliary opsin at 46848-87956 using GenBank contig order.

That's a striking coincidence in that antibody to acetylated alpha-tubulin was used as marker for stabilized microtubules in cilia and axons -- almost close enough for coupled expression especially when that contig piece is flipped (reverse complemented so that all the opsin exons are on the same strand). That brings the intergene distance to 8200 bp (end of opsin 53730 - start of tubulin 61901). That's something to keep in mind in terms of establishing syntenic orthologs in other lophotrochozoa.

Tardigrada: Hypsibius dujardini (water bear) tardigrade 0 opsins

A 5x genome project for Hypsibius dujardini, a phylum of microscopic ecdysozoan was approved in July 2007 but Broad has not yet begun trace reads on the small 70 mbp genome (suggesting densely spaced genes with small introns as this is not likely highly derived). It could prove very useful for opsins as tardigrades are basal to all of Arthropoda and so shed light on that last common ancester. In fact with accompanying centipede, horseshoe crab, amphipod, and priapulid genomes, the whole ecdysozoan ancester will be accessible.

The only known fossil specimens are found in Siberian mid-Cambrian deposits and much later amber. The older fossils have three pairs of legs rather than four, a simplified head morphology, and no posterior head appendages and probably represent a stem group of extant tardigrades. Aysheaia from the Burgess Shale might be related to tardigrades.

Nothing is currently known about photoreception or opsins in tardigrades -- or even if they have eyes. However it looks like we can expect some rhabdomeric opsins at the minumum in front of these pigment cups. However the current GSS and EST collections (about 6000 sequences) do not currently contain any convincing matches using various rhabdomeric and ciliary opsins as tblastn queries. Tardigrade photos and movies provided by Goldstein Lab

Tardi.png


Chelicerata: Ixodes scapularis (tick) 1 opsin

The genome project was completed long ago but has experienced a multi-year bottleneck in assembly release and publication. However contigs built from 19.4 million traces should become available to tblastn of the GenBank "wgs" division by late 2007. Ixodes has a very conservative genome (regretably 2.1 gbp in size), seemingly far less derived than drosophilids in matters such as intron, gene retention, and protein sequence conservation. This, in conjunction with the helpful phylogenetic position of chelicerate outgroup to the many insect genomes, has improved prospects for reconstructing the ancestal opsin repertoire of Arthropoda and eventually Protostomia and UrBilatera.

A large collection of annotated Ixodes ESTs is available at the DFCI Gene Index of which 3 are marked up (2 wrongly) as opsins. Using the Opsin Classifier, I recovered the full length gene for the first of these TC19272 on 24 Nov 07, intronated the transcript at the Trace Archives (4 introns, superb coverage), and added it to the classifier fasta collection as RHAB1_ixoSca. It classifies with rhabdomeric opsins (ie with deuterostome melanopsins) with a very respectable 57% maximal percent protein identity. The second and third intron have classical ancestral position (following GWSR and LAK) and phase (2 and 0). Synteny awaits assembly of large contigs -- adjacent exons are not spanned by single traces. An apparent ciliary opsin fragment in Ixodes was located using that of Platynereis dumerilii as probe, it is stored as CILI_ixoSca but needs further analysis.

Crustacea: Daphnia pulex (water flea) .. 37 opsins

An 8.7x genome assembly was released in July 2007 at JGI with further support at wFleaBase. This crustacean provides a potentially important outgroup to insects (together forming Pancrustacea). However the opsin story, summarized in a meeting abstract is an embarrassment of riches, not conducive to deducing ancestral arthropod genome content. The total number of opsin genes came in at 37, comprised of 22 rhabdomeric opsins (mostly long wavelength), 7 ciliary opsins (pteropsins), and 8 in a novel family without close affiliates. This seems excessive but Daphnia has ommatidia (compound eyes), circadian rhythms, and a need to assess water turbidity and depth. Planned in situ hybridization studies may illuminate biological roles of these opsins. The pteropsins are probably of most interest here.

Gene models have not been submitted yet to GenBank but are likely extractable by text query at wFleaBase. What is needed here however is not the clutter of 37 sequences but their collapse into UV, blue, long, pteropsin, and novel ancestral representatives. This would remove 'noise' from lineage-specific expansions. The intron structure could provide very important support to classification schemes.

The expansions may have arisen through retroprocessing (rather than segmental duplication) of a few master exonic genes, which would then be the orthologs to other arthropod opsins. Indeed the intronation pattern -- typically far more deeply conserved than protein sequence -- could link pteropsins more convincingly to lophotrochoan and deuterostome opsins than alignments with percent identities in the 20's.

This blast twilight zone is especially dangerous for photoreceptor opsins because they are embedded in much larger gene family of generic rhodopsin and GPCR which share many structural and signaling properties. A slowly evolving generic rhodopsin might well score higher than fast evolving photoreceptor opsins. Gene expansions are noted for markedly enhanced rates as copies neo- or subfunctionalize. The generic rhodopsin might also share diagnostic residues through convergence at least at the level of statistical signficance ambiguity. Consequently intron location/phase and synteny can provide important backup.

The synteny circle surviving at this phylogenetic depth will be local (optimistically Pancrustacean). That is, the blue opsin of Daphnia might in synteny with Drosophila (ie establish orthology) but not to Platynereis ciliary opsin much less any vertebrate opsin (eg encephalopsin). This could be remedied to some extent by ancestral gene order reconstruction. The degree to which synteny can contribute to validating orthology relations within opsins is not currently known.

Cnidaria: Carybdea marsupialis (jellyfish) cnidarian .. 0 opsins

Cnidarians are the earliest diverging invertebrates with multicellular light-detecting organs, called ocelli. Photodetectors include simple eyespots, pigment cups, complex pigment cups with lenses, and camera-type eyes with a cornea, lens, and retina. These remarkable eyes are located on sensory clubs called rhopalia with four lining the bell of Each houses six eyes: a pair of pit ocelli, a pair of slit ocelli, and two unpaired lens eyes with counterparts to cornea, cellular lens and retina of ciliated photoreceptors. Anatomically, ocelli have bipolar sensory photoreceptor cells interspersed among nonsensory pigment cells with the apical end making the light-receptor and the basal end forming an axon that synapses with second-order neurons to form what amounts to ocular nerves.

The spectral sensitivity of neritic (near-shore) lens eyes of a box jellyfish, Tripedalia cystophora recently considered by MM Coates et al was interpreted as a single vitamin A-1 based opsin with peak sensitivity near 500 nm (blue-green). However nothing was sequenced.

The most striking jellyfish from the perspective of a complex set of eyes is Carybdea marsupialis, as reviewed by VJ Martin. Antibody studies based on vertebrate cone/rod opsins are doubtful because of cross reactivity to generic GPCR proteins; again no opsins have been sequenced yet.. This would make a great genome to study provided the retroposon and base composition are not unwieldy. Nematostella and Hydra, whatever their other genomic merits, sits in the Anthozoa and Hydrozoa respectively, types of cnidarian lacking elaborate visual systems.

Vision has roles in the reproduction and feeding of cubomedusae which can find each other and chase, catch, and eat teleost fish. A patch of Pelagia nocticula 10 square miles in extent and 35 feet deep recently destroyed a salmon farm off Northern Ireland.

Porifera: Amphimedon queenslandica (sponge) and earlier metazoan lack opsins

Sponges lie at the base of multicellular animals. They are not noted for eyes. However demosponge larva do exhibit phototaxis (shadow seeking under coral rubble) but the action spectrum is reportedly a better fit to a flavin or carotenoid chromophore. The genome of Amphimedon queenslandica has been available for years at the Trace Archives but never assembled. The species was formerly called Reniera spp. and it is still carried under that name at JGI Genome. Consequently tblastn of contigs is not available without do-it-yourself assembly.

The Oakley group reported searching for sponge opsins but finding only "non-opsin, rhodopsin-class GPCR genes" from Amphimedon. Similarly, no opsins were located in the even earlier diverging placozoan Trichoplax, choanoflagellate Monosiga, and fungal genomes. This fits a picture of photoreceptor opsins first appearing subsequent to sponge in eumetazoa cnidarians. However these were not de novo genes but rather evolved out of the already-rich cauldron of GPCR gene copies.

Some later diverging species such as the model organism C. elegans lost all of their opsin genes, making them useless in Urbilateran ancestor reconstruction. This argues for much more intensive genomic sampling so as to sidestep the widespread problem of gene loss in model organisms.

Coming real soon!

Urochordata: Ciona intestinalis (tunicate) .. 2 opsins

Cephalochordata: Branchiostoma (amphioxus) .. 7 opsins

Platyhelminthes: Schmidtea mediterranea (planaria) .. 1 opsin

Lophotrochozoa: Capitella sp (annelid) .. 0 opsins

Lophotrochozoa: Lottia gigantea (limpet) + Aplysia californica (sea hare).. 0 opsins

Cnidaria: Nematostella stellata (anemone) .. 4 opsins

Cnidaria: Hydra magnipapillata (hydra) .. 2 opsins