Báo cáo khoa học: Identification of rice TUBBY-like genes and their evolution Qingpo Liu docx

In order to investigate the evolution and divergence of TULPs in eukaryotes, a phylogenetic, evolutionary and functional divergence analysis of the TUBBY-like gene family has been Keywor

Qingpo Liu

School of Agriculture and Food Science, Zhejiang Forestry University, Hangzhou, Lin’an, China

TUBBY-like proteins (TULPs) are present in

eukary-otes from single-celled to multicellular organisms The

first TUBBY gene was identified in obese mice [1] A

typical feature of TUBBY proteins is the

approxi-mately 270-amino acid tubby domain at their

C-termi-nal region Accordingly, a number of such genes have

been successively isolated from other organisms, such

as Homo, Gallus, Xenopus, Zea and Arabidopsis [2],

based on sequence characteristics Interestingly, these

genes form a small family in mammals, which consists

of TUBBY and four TULPs [1,3] By contrast, plants

appear to harbour a large number of TULPs [2,4]

Moreover, compared with the high divergence of the

N-terminal sequence of animal TULPs, most plant

TULPs contain a conserved F-box domain at the

cor-responding region [5]

Although the high conservation of the tubby domain

across species suggests that TULPs may carry out

cer-tain fundamental biological functions in common [4],

little is known about their target genes or precise

action mechanisms In animals, TULPs are important

for normal neuronal development and function [4] It has been shown that TULPs play crucial roles in vesic-ular trafficking [6], mediation of insulin signalling [7] and gene transcription [8] In Arabidopsis, Lai et al [2] have demonstrated that TULP9 (AtTLP9) interacts with Skp1-like 1 (ASK1) They speculated that, as well

as acting as transcription regulators, F-box domain-containing plant TULPs should have cellular function activities of F-box proteins in signal transduction Sup-pression and overexSup-pression analyses of Arabidopsis TULPs (AtTLPs) have shown that at least one AtTLP may function in the abscisic acid-regulated pathway [2]

Rice is one of the most important crops for human consumption The final completion of the Oryza sativa genome [9] has made it possible to identify all the TUBBY-like family members in this plant species at the genome-wide level In order to investigate the evolution and divergence of TULPs in eukaryotes, a phylogenetic, evolutionary and functional divergence analysis of the TUBBY-like gene family has been

Keywords

evolution; functional divergence; phylogeny;

rice; TUBBY-like

Correspondence

Q Liu, School of Agriculture and Food

Science, Zhejiang Forestry University,

Hangzhou, Lin’an, China

Fax: +86 571 86971117

Tel: +86 571 86971611

E-mail: liuqp@genomics.org.cn

(Received 28 September 2007, revised

7 November 2007, accepted 12 November

2007)

doi:10.1111/j.1742-4658.2007.06186.x

The identification of TUBBY-like genes in organisms ranging from single-celled to multicellular eukaryotes has allowed the phylogenetic history of this gene family to be traced back to the early evolutionary stages of eukaryote development Rice TUBBY-like genes were located on chromo-somes 1, 2, 3, 4, 5, 7, 8, 11 and 12 without any obvious clustering On a genomic scale, it was revealed that the rice TUBBY-like gene family proba-bly evolved mainly through segmental duplication produced by polyploidy The altered selective constraints (or site-specific rate changes), related to functional divergence during protein evolution between plant and animal TUBBY-like genes, were statistically significant Based on posterior proba-bility analysis, five amino acid sites (103, 312, 315, 317 and 319) are thought to be responsible for functional divergence

Abbreviations

EST, expressed sequence tag; GEO, gene expression omnibus; NCBI, National Center for Biotechnology Information; RED, Rice Expression Database; RGP, Rice Genome Project; TIGR, Institute for Genomic Research; TULP, TUBBY-like protein.

performed This first description of the whole rice

TUBBY-like gene family will aid in our understanding

of the function of TULPs in plants

Results and Discussion

Identification and sequence analysis

of rice TULPs

After carefully surveying the rice genome, 14 genes

were defined as rice TULPs (OsTLPs; Table 1)

Domain analysis showed that, with one exception

(OsTLP13), a conserved F-box domain (PF00646) was

found at the N-terminal region of OsTLPs In addition

to the tubby (PF01167) and F-box domains, most

OsTLPs had two PROSITE signature patterns, termed

TUB1 (PS01200) and TUB2 (PS01201), at their

C-ter-minal region, evidence that strongly supports their

reliability as members of the rice TUBBY-like family

The results of expressed sequence tag (EST) and

cDNA blast searches showed that 13 of the 14

OsTLPs matched at least one significant EST sequence,

and 11 of the 14 OsTLPs exactly matched a

corre-sponding full-length cDNA sequence in the GenBank

or KOME database (Table 1) These results indicated

that most TULPs are expressed in the rice genome

The comparison of gene structure showed a

con-served exon number pattern in OsTLPs, although the

length of introns was different (Table 1) With three

exceptions (OsTLP7, OsTLP13 and OsTLP14), all of

the OsTLPs had four exons Further analysis found

that the F-box domain, except for OsTLP13, was

encoded by the first exon, whereas the tubby domain

was encoded by the following three exons

Phylogenetic analysis blast search against the GenBank database showed that both single-celled (Ostreococcus tauri, Tetrahy-mena thermophila, etc.) and multicellular (mammals, plants, etc.) organisms possessed tubby domain-con-taining proteins, indicating their functional importance for eukaryotes In this study, in order to avoid biased analysis, the C-terminal tubby domain, rather than the highly divergent N-terminus, was used to perform phy-logenetic analysis Supplementary Fig S1 shows the multiple sequence alignment of tubby domains The phylogenetic trees reconstructed using the neighbour-joining and minimal evolution methods in mega v3.1 (trees not shown) and the neighbour-joining method in phylip(Fig 1) revealed similar topologies

At first glance, three clades (plant, animal and mixed clades) were evident in the tree (Fig 1) In animals, the T thermophila TULP (TtTLP) was evolutionarily distant from the other animal TULPs, suggesting long periods of divergence from this metazoan Further analysis showed that invertebrate (insects, nematodes and Echinodermata) and vertebrate metazoans were not clustered into distinct clades, indicating that the divergence of animal TULPs probably occurred before the invertebrate–vertebrate split In addition, mamma-lian TULPs were clustered into four subclades, three

of which were evolutionarily clustered together with Actinopterygii TULPs; this indicates that divergence may have predated the Mammalia–Actinopterygii split With five exceptions (AtTLP8, OsTLP13, PtaTLP10, CrTLP1 and CrTLP2), plant TULPs were tightly clus-tered together, supported by highly significant boot-strap values (996; Fig 1) In the plant-specific clade,

Table 1 List of rice TUBBY-like family members.

OsTLP

Accession

Amino

monocotyledon and dicotyledon TULPs were not

found in distinct groups, but, instead, were

inter-spersed, suggesting that the significant expansion of

plant TULPs should be no younger than the

diver-gence time between monocots and dicots

(approxi-mately 200 million years ago [10])

The mixed clade is very special, and consists of one

fungus, one euglenozoan and five plant TUBBY-like

proteins In addition, one tubby domain-containing

protein was identified in both Plasmodium yoelii yoelii

and Plasmodium falciparum These two proteins were

excluded from phylogenetic analysis because of their

failure in the chi-squared test for homogeneity of

amino acid composition However, if these sequences

were arbitrarily included in the phylogenetic analysis,

they were clearly classified into this clade (bootstrap

value 920; tree not shown) Although tubby

domain-containing proteins were found in several protozoans,

this type of protein was only identified in one fungus

after an exhaustive database search It should be noted

that O tauri belongs to the Prasinophyceae, that

diverged at the base of the monophyletic green lineage,

which includes green algae and land plants [11] Thus,

the identification of one TULP in O tauri and three

TULPs in Chlamydomonas reinhardtii (CrTLPs)

allowed the origin of this gene family to be traced

back to the early evolutionary stages of eukaryote

development

Genomic organization of OsTLPs

Gene families can arise through tandem amplification,

resulting in a clustered occurrence, or segmental

dupli-cations of chromosomal regions, resulting in a scat-tered occurrence of family members [12] It was observed that OsTLPs were located on chromosomes

1, 2, 3, 4, 5, 7, 8, 11 and 12 By contrast with only one OsTLP found on chromosomes 3, 4, 7, 8, 11 and 12, three (OsTLP5, OsTLP9 and OsTLP12), two (OsTLP8 and OsTLP13) and three (OsTLP1, OsTLP10 and OsTLP11) genes were located on chromosomes 1, 2 and 5, respectively (Fig 2A) Although the distribution

of OsTLPs on rice chromosomes was obviously uneven, no two OsTLPs were found to be located

Fig 1 Phylogenetic tree of eukaryote TUBBY domains The

neighbour-joining method wrapped in PHYLIP [28] was used to

reconstruct the phylogenetic tree based on the multiple sequence

alignment of tubby domains (supplementary Fig S1) The numbers

beside the branches represent bootstrap values (‡ 600) based on

1000 replications To identify the species of origin for each tubby

domain, a species acronym is included before the protein name:

Aa, Aedes aegypti; Ag, Anopheles gambiae; Am, Apis mellifera;

At, Arabidopsis thaliana; Bt, Bos taurus; Ca, Cicer arietinum; Cb,

Caenorhabditis briggsae; Ce, Caenorhabditis elegans; Cf, Canis

familiaris; Cr, Chlamydomonas reinhardtii; Dm, Drosophila

mela-nogaster; Dp, Drosophila pseudoobscura; Dr, Danio rerio; Ec,

Encephalitozoon cuniculi; Gg, Gallus gallus; Hs, Homo sapiens;

Lm, Leishmania major; Lp, Lemna paucicostata; Mam, Macaca

mulatta; Mm, Mus musculus; Mt, Medicago truncatula; Os, Oryza

sativa; Ot, Ostreococcus tauri; Pc, Pyrus communis; Pt, Pan

trog-lodytes; Pta, Populus trichocarpa; Pxa, Platanus · acerifolia; Rn,

Rattus norvegicus; Sp, Strongylocentrotus purpuratus; Tc,

Triboli-um castaneTriboli-um; Tn, Tetraodon nigroviridis; Tt, Tetrahymena

ther-mophila; Xl, Xenopus laevis; Xt, Xenopus tropicalis.

close to each other, for example on the same scaffolds

or bacterial artificial chromosomes Thus, segmental

duplications probably contributed to the expansion of

the rice TUBBY-like gene family To test this

hypothe-sis, the method of Schauser et al [12] was performed

to investigate the evolutionary relationships between

duplicated segments In this way, five pairs of

dupli-cated segments, including OsTLP1⁄ 5, OsTLP4 ⁄ 6,

OsTLP7⁄ 14, OsTLP9 ⁄ 11 and OsTLP10 ⁄ 12, were

iden-tified (Fig 2B) Further examination of the rice dupli-cation blocks identified by Yu et al [13] and Wang

et al [14] revealed that the five pairs of OsTLPs con-stituted three duplication blocks corresponding to part

of the long arm of chromosome 1 (OsTLP9, OsTLP12 and OsTLP5) and part of the long arm of chromo-some 5 (OsTLP11, OsTLP10 and OsTLP1), part of the short arm of chromosome 3 (OsTLP14) and part

of the long arm of chromosome 7 (OsTLP7), and part

Fig 2 Genomic organization of OsTLPs (A) Localization of OsTLPs on rice chromosomes Black boxes indicate the three duplication blocks between chromosomes 1 and 5, 3 and 7, and 11 and 12 The relative sizes of chromosomes are derived from RGP (B) Detection of seg-mental duplications in regions of the rice genome encompassing OsTLPs The sequences of 10 proteins surrounding each OsTLP (five on each side) were concatenated to form one block A vertical black bar indicates the concatenation of two protein sequences This was per-formed for all 14 OsTLPs, resulting in 14 blocks, which were then searched against each other using a reciprocal best-hit BLAST strategy The five pairs of OsTLPs identified resulting from segmental duplications are shown here.

of the short arm of chromosome 11 (OsTLP6) and

part of the short arm of chromosome 12 (OsTLP4)

The three pairs (OsTLP9⁄ 11, OsTLP12⁄ 10 and

OsTLP5⁄ 1) located on chromosomes 1 and 5 may

originate from an ancient whole genome duplication,

followed by a segmental inversion Another two pairs

(OsTLP6⁄ 4 and OsTLP7 ⁄ 14) may be the result of

recent segmental duplication of chromosomes 11 and

12 and chromosomes 3 and 7, respectively [13,14]

With regard to OsTLP8 and OsTLP13, they may have

arisen as a result of duplication events, and lost their

counterparts over the long period of evolution, because

there was only one copy of each in the duplicated

regions on chromosome 2 This explanation is

reason-able, as it has been shown that the rice genome was

probably generated through two rounds of ancient

polyploidy events that were followed by massive gene

losses and numerous chromosome rearrangements [15]

Functional divergence (altered functional

constraint) analysis

A maximum likelihood test of functional divergence

was performed on the basis of the Gu method [16],

using the program diverge [17], which evaluates the

shifted evolutionary rate after gene duplication or

spe-ciation [18] The advantage of the Gu method [16] is

that it is not sensitive to saturation of synonymous

sites The estimation was based on the phylip

neigh-bour-joining tubby domain tree (Fig 1) The result

showed that the coefficient of type I functional

diver-gence between the plant and animal clades was

statisti-cally significant (h = 0.387 ± 0.149; likelihood ratio

test statistic, 6.669; P < 0.05), indicating that

signifi-cantly different site-specific shifts of evolutionary rate

may take place at certain amino acid sites [18] between

plant and animal tubby domains In order to identify

these variant amino acid sites, the posterior probability

of divergence was determined for each site The results

showed that the functional divergence between plant

and animal TUBBY-like proteins could be partially

attributed to variation on at least five amino acid sites

(103, 312, 315, 317 and 319, counting from PtaTLP10;

supplementary Fig S1 and Fig 3) Boggon et al [8]

performed X-ray crystallographic analysis of the tubby

domain of mouse TUBBY and found a unique protein

structure: a 12-stranded b-barrel conformation filled

with a central hydrophobic core that traversed the

entire barrel It was observed that these five amino

acids fall within the fifth (E5, site 103) and ninth

(E9A, site 312; E9B, site 319) b-strands, and the loop

between E9A and E9B (sites 315 and 317)

(supplemen-tary Fig S1)

Santagata et al [19] demonstrated experimentally that the amino acids that interact with l-a-glycero-phospho-d-myo-inositol 4,5-bisphosphate (GPMI-P2) are mostly in b-strands 4, 5 and 6 and helix 6A More importantly, three positively charged amino acid resi-dues, R332, R363 and K330 (corresponding to sites 103, 182 and 101 in this study), were found to be crucial for the tubby domain of mouse TUBBY protein to bind phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] [19] Figure 3 shows that site 103 (Qk= 0.877) is invariant arginine in animal tubby domains, a result supporting its importance for animal TULPs specifically binding a number of phosphory-lated phosphoinositides [20] By contrast, the same position in plant tubby domains contains several amino acids (arginine, serine or lysine) with different chemical properties, such as the uncharged polar amino acid serine (S) This variation may be explained

as a relaxed selective constraint at site 103 in plant tubby domains In addition, it was observed that site

182 was not an arginine (R) and showed a plant-spe-cific deletion (supplementary Fig S1) These results suggest that at least some of the plants may have lost their ability to bind phosphatidylinositol phosphates Boggon et al [8] observed a groove of highly posi-tive charge that was bordered at the top by helix H8 and at the bottom by the large 7–8 loop and the three-stranded ‘extra’ 9ABC sheet The result showed that the amino acid sites 312, 315, 317 and 319 were func-tional divergence related, in which one site was located

at E9A (site 312) and E9B (site 319) respectively, and two sites (315 and 317) were positioned in the E9A– E9B loop (supplementary Fig S1) It was observed that the four amino acid sites were significantly con-served in plants (Fig 3), indicating that strong func-tional constraints were imposed on these sites In comparison with plants, great variation was observed

in these sites in animal tubby domains Of these sites, site 317 was predicted to be highly functional diver-gence related (Qk= 0.954) It was observed that the chemical properties of the amino acid at site 317 were significantly different between plant and animal tubby domains In plants, the amino acid at site 317 was the invariant nonpolar leucine (L), whereas it was changed

to uncharged polar serine (S), threonine (T) or aspara-gine (N) in animals (Fig 3)

Molecular structural and genetic analyses have sug-gested a common function for animal tubby domains that can bind to double-stranded DNA and phospha-tidylinositol phosphates [4,8] With regard to the N-terminus, although this region shows a lack of con-servation in animals, it is able to activate transcription [8] Unlike animals, the N-terminal region of most

plant TUBBY-like family members often contains a well-conserved F-box domain Experimental evidence has shown that AtTLP1, AtTLP2, AtTLP3, AtTLP6, AtTLP7, AtTLP9, AtTLP10 and AtTLP11 are expressed in all tested organs, whereas AtTLP5 and AtTLP8 are tissue specifically expressed in Arabidopsis [2] After querying the rice dbEST database at the National Center for Biotechnology Information (NCBI), it was found that, with three exceptions (OsTLP11, OsTLP12 and OsTLP13), OsTLP genes showed a tissue-specific expression pattern, although most were expressed in nearly all the examined tissues (Table 2) However, the expression of several phylo-genetically closely related OsTLP genes showed similar

or overlapping tissue specificity, for example OsTLP1 and OsTLP5 (Table 2) Interestingly, TULPs can be expressed with cell-type specificity and can be regu-lated by their subcellular localization [4,21] He et al [21] found that, in hypothalamic neurones, TUB was localized in the cytoplasm and nucleus, whereas, in photoreceptor cells, it appeared to be found only in the cytoplasm The reason for the localization of TULPs in different cell populations still remains unknown In addition, Lai et al [2] demonstrated that AtTLP9 might participate in the abscisic acid signal-ling pathway The Rice Expression Database (RED) [22] and gene expression omnibus (GEO) in NCBI were also queried; it was found that OsTLP4, OsTLP5, OsTLP7, OsTLP9, OsTLP10 and OsTLP12 were prob-ably involved in the abscisic acid and gibberellin sig-nalling processes Nevertheless, more in-depth studies are needed to establish their distinctive activities and biological roles

Experimental procedures

Collection of rice TULPs

The consensus sequence of the tubby domain (PF01167) was obtained from the Pfam database The Arabidopsis TUBBY-like proteins (accession numbers: AtTLP1, AF487267; AtTLP2, AY045773; AtTLP3, AY045774;

Fig 3 Functional divergence related amino acid site candidates (Q k > 0.6) A site-specific profile based on the posterior probability (Qk) was used to identify critical amino acid sites that were respon-sible for functional divergence [18] between the animal and plant tubby domains According to the definition, a large Q k value indi-cates a high possibility that the functional constraint (or the evolu-tionary rate) of a site is different between two clusters (A) Animals; (B) Plants; and (C) Posterior probability values (Q k ) of five amino acid sites.

AY092403; AtTLP8–AtTLP10, AF487269–AF487271;

AtT-LP11, AY046922) were downloaded from the GenBank

database In an attempt to obtain all the TULP members,

the rice protein sequences collected in the Rice Genome

Project (RGP) [9], Institute for Genomic Research (TIGR)

and NCBI were downloaded to construct a local rice

pro-tein database With the tubby domain consensus and the

ArabidopsisTUBBY-like proteins (AtTLPs) as queries,

psi-blastwas seeded to search the local and Oryza sativa

pro-tein database in NCBI with an e-value of 10 Moreover, a

psi-blastsearch against the nonredundant GenBank

data-base was performed to collect tubby domain-containing

proteins in other species using the tubby domain consensus

sequence as query The collected Arabidopsis and other

published TULPs were used to construct a hidden Markov

model (HMM) profile; this was followed by an hmmer

(version 2.3.2) [23] search of the rice proteome In addition,

a tblastn search against the rice genomic sequences

depos-ited in RGP, NCBI and TIGR was also conducted

Signifi-cant hits were collected and redundant hits were removed

by manual inspection The domain architecture of

eukary-ote TUBBY-like preukary-oteins was analysed using the domain

analysis program interproscan [24] with the default

parameters The accession numbers of the collected TULPs

are listed in supplementary Table S1

Analysis of rice TULP evolution

TULPs were found to show a scattered distribution pattern

on rice chromosomes Consequently, segmental duplication

was assumed to have contributed to the expansion of this

gene family Schauser et al [12] demonstrated that the

effective way to detect this type of duplication event was to

identify additional paralogous protein pairs in the

neigh-bourhood of each of the family members Accordingly, the present study focused on 10 proteins encoded by genes flanking each of the 14 rice TULPs (five on each side)

Multiple sequence alignment and construction

of the phylogenetic tree

Alignment of the tubby domains was performed using the clustalw program [25] with the default parameters The multiple aligned sequences were initially subjected to a chi-squared analysis for homogeneity of amino acid com-position, implemented in tree-puzzle v5.2 [26] Sequences that failed in this test were excluded To investigate the evolutionary relationships amongst tubby proteins, a phy-logenetic tree was reconstructed by employing the neigh-bour-joining method and the minimal evolution method wrapped in mega v3.1 [27] For both methods, the param-eters p-distance model and pairwise deletion of gaps⁄ miss-ing data were selected In addition, phylip [28] was employed to reconstruct a neighbour-joining tree from the same data A bootstrap test of phylogeny was performed with 1000 replications for each method The programs njplot and mega v3.1 [27] were used to display the phy-logenetic trees

Estimation of functional divergence

diverge, a program developed by Gu and Velden [17], was used to detect functional divergence between members of a protein family [29] In the TUBBY-like gene family, two gene clusters of interest, including plant and animal TULPs, were selected The coefficient of type I functional divergence h and the likelihood ratio test statistic between

Table 2 EST-derived expression profile for rice TUBBY-like genes.

OsTLP

Tissue

OsTLP11a

+, Presence of gene sequences in EST collection derived from the indicated tissues.

a No significant EST hit was found for OsTLP11 in the present EST database, indicating that this gene might be weakly expressed in rice.

the two clusters were quickly calculated A h value

signifi-cantly greater than zero indicates altered selective

con-straints of amino acid sites after gene duplication [18]

Acknowledgement

This project was supported by the China Postdoctoral

Science Foundation (No 20060390348)

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Supplementary material

The following supplementary material is available

online:

Fig S1 Multiple sequence alignment of eukaryote tubby domains

Table S1 Accession numbers of collected TULPs in 33 species

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