Báo cáo khoa học: Retention of the duplicated cellular retinoic acid-binding protein 1 genes (crabp1a and crabp1b) in the zebrafish genome by subfunctionalization of tissue-specific expression doc

These two crabp1 genes share the same gene structure as the mammalian CRABP1 genes and encode proteins that show the highest amino acid sequence identity to mammalian CRAB-PIs.. Phylo-ge

protein 1 genes (crabp1a and crabp1b) in the zebrafish

genome by subfunctionalization of tissue-specific

expression

Rong-Zong Liu1, Mukesh K Sharma1, Qian Sun1, Christine Thisse3, Bernard Thisse3,

Eileen M Denovan-Wright2and Jonathan M Wright1

1 Department of Biology, Dalhousie University, Halifax, Nova Scotia, Canada

2 Department of Pharmacology, Dalhousie University, Halifax, Nova Scotia, Canada

3 Institut de Ge´ne´tique et Biologie Mole´culaire et Cellulaire, Department of Developmental Biology, UMR 7104, CNRS ⁄ INSERM ⁄ ULP,

CU de Strasbourg, Illkirch, France

Cellular retinoid-binding proteins belong to the large

family of low molecular mass (
15 kDa) intracellular

lipid-binding proteins (iLBP) that bind fatty acids,

reti-noids and steroids [1–3] In mammals, two different

groups of cellular retinoid-binding proteins with

dis-tinctive binding properties have been identified, the

cellular retinol-binding proteins (CRBPs) and the

cel-lular retinoic acid-binding proteins (CRABPs) CRBPs,

including CRBPI, CRBPII, CRBPIII and CRBPIV, show greatest binding affinity for retinol and retinal, but do not bind retinoic acid or retinyl esters [1,4–6]

In contrast, the mammalian CRABPs, CRABPI and CRABPII, bind retinoic acid but not retinol or retinal However, the affinity of the rat CRABPI for all-trans

RA (Kd¼ 4 nm) is much greater than that of CRAB-PII (Kd¼ 64 nm), and the same relative affinity for

Keywords

crabp1; embryonic development; gene

duplication; gene expression;

subfunctionalization

Correspondence

J M Wright, Department of Biology,

Dalhousie University, Halifax, Nova Scotia,

Canada, B3H 4J1

Fax: +1 902 4943736

Tel: +1 902 4946468

E-mail: jmwright@dal.ca

Website: http://www.dal.ca/biology2/

(Received 4 March 2005, revised 2 May

2005, accepted 16 May 2005)

doi:10.1111/j.1742-4658.2005.04775.x

The cellular retinoic acid-binding protein type I (CRABPI) is encoded by a single gene in mammals We have characterized two crabp1 genes in zebra-fish, designated crabp1a and crabp1b These two crabp1 genes share the same gene structure as the mammalian CRABP1 genes and encode proteins that show the highest amino acid sequence identity to mammalian CRAB-PIs The zebrafish crabp1a and crabp1b were assigned to linkage groups 25 and 7, respectively Both linkage groups show conserved syntenies to a seg-ment of the human chromosome 15 harboring the CRABP1 locus Phylo-genetic analysis suggests that the zebrafish crabp1a and crabp1b are orthologs of the mammalian CRABP1 genes that likely arose from a teleost fish lineage-specific genome duplication Embryonic whole mount in situ hybridization detected zebrafish crabp1b transcripts in the posterior hind-brain and spinal cord from early stages of embryogenesis crabp1a mRNA was detected in the forebrain and midbrain at later developmental stages

In adult zebrafish, crabp1a mRNA was localized to the optic tectum, whereas crabp1b mRNA was detected in several tissues by RT-PCR but not by tissue section in situ hybridization The differential and complement-ary expression patterns of the zebrafish crabp1a and crabp1b genes imply that subfunctionalization may be the mechanism for the retention of both crabp1duplicated genes in the zebrafish genome

Abbreviations

CRABPIa and CRABPIb, cellular retinoic acid-binding protein type I a and b; CRBP, cellular retinol-binding protein; hpf, hours post fertilization; iLBP, intracellular lipid-binding protein; LG, linkage group; ORF, open reading frame; RA, retinoic acid.

all-trans retinoic acid (RA) is also true for human

CRABPI (Kd¼ 0.06 nm) and CRABPII (Kd¼

0.13 nm) [7]

The function of mammalian CRABPI is not fully

understood The highly conserved amino acid

seq-uence of CRABPI among different species and its

distinct tissue-specific expression patterns during

development and in adulthood suggest that it has an

essential role in retinoic acid targeting and

metabo-lism Homozygous CRABPI knockout mice, however,

exhibit no overt abnormalities and appear essentially

normal in terms of viability and fertility [8–10] As

such, CRABPI function may be dispensable or

com-pensated by another member of the CRABPI⁄

CRAB-PII multigene family in these knockout mice A

recent investigation of CRABPI function using a

murine embryonic stem cell line deleted for crabp1

showed that homozygous deletion of this gene results

in decreased intracellular RA concentrations and

increased CRABPII expression suggesting a role for

CRABPI in the RA homeostasis in cells and

regula-tion of CRABPII expression [11] Further evidence

that CRABPI may modulate RA signaling is the

localization of CRABPI in both the cytoplasm and

nucleus [12–14] Specific expression of CRABPI in the

mammalian olfactory bulb and spinal cord, which are

recognized as prominent sites of ongoing plasticity

and response to RA, implies that CRABPI is

involved in neurogenesis [15–18]

The mammalian CRABPI and CRABPII proteins

are encoded by single genes which, like all other

para-logous members of the vertebrate iLBP family, consist

of four exons separated by three introns [1] Except for

the gene structure of CRABPI in pufferfish (Fugu

rubr-ipes) [19], no detailed characterization of CRABPI

genes has been reported in fishes, the largest and most

diverse group of vertebrates Furthermore, only a

sin-gle copy of the gene encoding CRABPI has been

iden-tified in vertebrates Here we report the finding of

duplicated genes coding for CRABPI (designated

crabp1a and crabp1b) in the zebrafish genome Gene

structure, syntenic relationship and primary protein

sequence of the zebrafish crabp1a and crabp1b are

well conserved with their orthologous mammalian

CRABP1s Comparative genomic analysis suggests that

the zebrafish duplicated crabp1a and crabp1b genes

may have arisen from a teleost fish-specific

chromoso-mal or whole genome duplication The differential

distribution of crabp1a and crabp1b transcripts during

development and in adult zebrafish tissues implies

subfunctionalization after their duplication, which

might be a mechanism for preservation of the crabp1

duplicates in the zebrafish genome

Results

Determination of cDNA sequence and gene structure of the zebrafish crabp1a

A zebrafish EST sequence (GenBank accession number BI533516) showing sequence similarity to the mamma-lian CRABPI was identified and retrieved from the GenBank database Complete and overlapping 3¢ and 5¢ cDNA ends of the putative zebrafish crabp1 (desig-nated crabp1a) were PCR-amplified using primers based on the EST sequence, cloned and sequenced The zebrafish crabp1a cDNA sequence was 719 bp including a 56 bp 5¢-UTR and a 246 bp 3¢-UTR (Gen-Bank accession number AY242125) A polyadenylation signal was located 14 bp upstream of the poly A tail

in the cDNA clones A 417 bp open reading frame (ORF) for the zebrafish crabp1a cDNA was identified, which codes for a peptide of 138 amino acids with a theoretical molecular mass of 15.68 kDa and a predic-ted isoelectric point of 5.05 The deduced amino acid sequence of the zebrafish CRABPIa showed highest identity with the mammalian and pufferfish CRABPIs (84–86%) (Fig 1A), followed by mammalian and zebrafish CRABPIIs (58–69%), mammalian and zebra-fish CRBPIs (28–34%), mammalian and zebrazebra-fish CRBPIIs (28–30%), human CRBPIII (29%) and CRBPIV (30%) (data not shown) Comparison of the amino acid sequence of the zebrafish CRABPIa with its mammalian and pufferfish orthologs showed that there is a proline insertion in the amino acid sequence immediately following the initiator methionine (Fig 1A)

Sequenced genomic DNA segments with identity to the cloned cDNA of the zebrafish crabp1a were identi-fied by a BlastN search and retrieved from the zebra-fish genome database (Wellcome Trust Sanger Institute) An assembly (GenBank accession number BX296538) contained the sequence of exon 1 (129 bp), intron 1 (5828 bp), exon 2 (179 bp), a part of intron 2 and a 5¢ upstream sequence of crabp1a A scaffold sequence, Zv4_scaffold2030.1, harbored the sequence

of both exon 3 (114 bp), intron 3 (3262 bp) and exon

4 (298 bp), and part of the sequence for intron 2 The cDNA and genomic DNA sequences showed differ-ences between three nucleotides in exon 2, resulting in alteration of the 15th codon of exon 2 from GCC to GCA, 44th codon CGT to CGC and 47th codon GAA

to GAG In spite of these nucleotide differences, the amino acids encoded by these codons remained unchanged suggesting that these changes represent allelic variants The RNA donor and acceptor splice sites present in each intron of the zebrafish crabp1a

gene conformed to the GT-AG rule [20] The zebrafish

crabp1a gene structure, consisting of four exons

and three introns, is the same as the mammalian and

pufferfish crabp1 genes (Fig 1B) Exon 1 of the

crabp1a genomic sequence, like the cDNA sequence,

had an insertion of a proline codon (CCT)

immedi-ately following the initiator methionine relative to

mammalian and pufferfish orthologs [1,19]

5¢-RLM-RACE generated a single product

corres-ponding to the position of the 7-methyl G cap of the

mature crabp1a mRNA (data not shown) Alignment

of the nucleotide sequence of the cloned

5¢-RLM-RACE product with the genomic sequence assigned

the transcription start site to the 56 bp upstream of the initiation codon (data not shown)

Identification of a second crabp1 gene, crabp1b

A tblastn search using the deduced amino acid sequence of the zebrafish CRABPIa as a query identi-fied a second crabp1-like gene in the zebrafish genome (GenBank accession number BX663612) This gene codes for an amino acid sequence showing similarity

to the zebrafish CRABPIa and the mammalian CRAB-PIs (Fig 1A) The structure and coding capacity of this gene was identical to that of the mammalian and

A

B

Exon 1 Intron 1 Exon 2 Intron 2 Exon 3 Intron 3 Exon 4

24 aa 60 aa 38 aa 16 aa

23 aa 60 aa 38 aa 16 aa

7629 bp 6815 bp 7470 bp

23 aa 60 aa 38 aa 16 aa

1959 bp 3453 bp 1222 bp

23 aa 60 aa 38 aa 16 aa

23 aa 60 aa 38 aa 16 aa

Fig 1 Alignment of the amino acid sequences of the fish and mammalian CRABPIs and comparison of their gene structures (A) Zebrafish (Zf) CRABPIa (GenBank accession number: AAP44333) and CRABPIb (AAT38218) were aligned with the pufferfish (Pf; O42386), human (Hm; P29762) and mouse (Ms; P02695) CRABPIs Dots indicate amino acid identity and dashes represent gaps Positions of amino acids are marked and numbered Amino acid sequence identity values between the zebrafish CRABPIs and the pufferfish, human and mouse

CRAB-PIs are indicated at the end of each alignment A proline insertion in the zebrafish CRABPIa is indicated by a ‘.’ (B) Comparison of the

exo-n ⁄ intron organization of the zebrafish (Zf) crabp1 genes with the orthologous genes from pufferfish (Pf), human (Hm) and mouse (Ms) Exons are shown as boxes and introns as lines The number of amino acids encoded by each exon is shown above the boxes The size of each complete intron is indicated The complete sequence of the second intron in crabp1a has not been determined (indicated by dashes) The human and mouse CRABP1 gene sequences were obtained from GenBank (accession numbers NT_086829 and NT_039474) The struc-ture of the pufferfish crabp1 gene was defined based on reference [19].

pufferfish CRABP1 genes (Fig 1B) We designated this

gene as crabp1b 5¢-RLM-RACE located a single

tran-scription start site 109 bp upstream of the initiation

codon (data not shown) The zebrafish crabp1b gene

was approximately 23 kb in length (Fig 1B)

The complete cDNA sequence of the zebrafish

crabp1b (GenBank accession number AY616861) was

determined by sequencing cloned 5¢-RLM-RACE and

3¢-RACE products The primers used for the cDNA

cloning were designed based on the coding sequence of

the zebrafish crabp1b gene The length of the complete

cDNA sequence was 895 bp excluding the poly(A) tail

A polyadenylation signal was identified in the 3¢-UTR

13 nucleotides upstream of the polyadenylation site

The cDNA sequence contained an ORF of 414 bp

coding for a polypeptide of 137 amino acids The

deduced amino acid sequence of the zebrafish

CRAB-PIb showed highest identity to the zebrafish CRABPIa

(88%) and the mammalian and pufferfish CRABPIs

(84–85%) (Fig 1A), lower sequence identity to the

mammalian and fish CRABPIIs (58–71%) and lowest

identity to the mammalian and fish CRBPs (25–35%)

(data not shown)

The crabp1a and crabp1b genes arose from

a fish-specific chromosomal duplication

Phylogenetic analysis of the mammalian and fish

cellu-lar retinoid-binding proteins revealed two distinct

clades: CRBPs and CRABPs (Fig 2) The zebrafish

CRABPIa and CRABPIb clustered with the

mamma-lian and pufferfish CRABPIs in the same clade with a

robust bootstrap value of 998⁄ 1000 The gene

phylo-geny suggests that the zebrafish crabp1a and crabp1b

are orthologs of the mammalian and pufferfish genes

for CRABPI, which may have arisen from a

fish-speci-fic chromosomal or whole genome duplication after

the divergence of the tetrapod and fish lineages some

300 million years ago [21]

Linkage group (LG) assignment of the zebrafish

crabp1genes was determined by radiation hybrid

map-ping using the LN54 panel [22] The zebrafish crabp1a

gene was assigned to LG 25 with a mapping distance

of 26.53 cR to marker Z7306, while crabp1b was

assigned to LG 7 at a site 2.94 cR to marker fd15c06

(mapping data available on request) Both zebrafish

crabp1 genes displayed conserved syntenies with the

human CRABP1 gene on chromosome 15 (15q24)

([23]; http://www.ncbi.nlm.gov/locuslink) (Fig 3) The

conserved syntenies on the human chromosome 15

with both zebrafish crabp1 genes were distributed

within the same chromosomal region 15q15–15q26

(Fig 3) Another pair of duplicated zebrafish genes,

foxb1.1 and foxb1.2, were also found to be located on the zebrafish LG 7 and LG 25, respectively The single human orthologous FOXB1 gene is located at position 15q21-q26

Differential distribution of the crabp1a and crabp1b transcripts during embryonic and larval development

The spatio-temporal distribution of the zebrafish crabp1a and crabp1b transcripts during embryonic and

Fig 2 Phylogenetic analysis of cellular retinoid-binding proteins The bootstrap neighbor-joining phylogenetic tree was constructed using CLUSTALX [23] The zebrafish (Zf) intestinal type fatty acid-bind-ing protein (I-FABP) amino acid sequence (GenBank accession num-ber AAF00925) served as an outgroup The bootstrap values (based

on number per 1000 replicates) are indicated to the right of each node Amino acid sequences used in this analysis include zebrafish CRBPIa (AAQ54326), zebrafish CRBPIb(AAR31829), human (Hm) CRBPI (P09455), mouse (Ms) CRBPI (Q00915), rat (Rt) CRBPI (P02696), zebrafish CRBPIIa (AAL38648), zebrafish CRBPIIb (AAT40241), human CRBPII (P50120), mouse CRBPII (Q08652), rat CRBPII (P06768), human CRBPIII (P82980), human CRBPIV (AAN61071), zebrafish CRABPIa (AAP44333) and CRABPIb (AAT38218), human CRABPI (P29762), mouse CRABPI (P02695), pufferfish (Pf) CRABPI (O42386), zebrafish CRABPIIa (AAQ85530), zebrafish CRABPIIb (AAW23987), human CRABPII (P29373), mouse CRABPII (P22935), and rat CRABPII (P51673) Scale bar ¼ 0.1 substitutions per site.

larval development was determined by whole mount

in situhybridization (Figs 4 and 5) The two duplicate

paralogous genes showed differential and mostly

non-overlapping mRNA distribution patterns in the

devel-oping CNS The zebrafish crabp1b transcripts were

detected during the middle somitogenesis stage at 17 h

post fertilization (hpf) in the primary neurons

through-out the spinal cord and the trigeminal placode

(Fig 4A1–3) At 24 hpf, crabp1a mRNA was first

detected in the neurohypophysis and the epidermis of

the tail bud (Fig 4B1–3) In comparison, crabp1b

mRNA-specific hybridization signal was distributed

in the anterior and posterior spinal cord, ventro-lateral

part of rhombomere 7 in the posterior hindbrain, vent-ral part of the anterior somites, hypaxial muscles and the tail bud (Fig 4B4–6 and 4C1–4) A weak crabp1b-specific hybridization signal was present in rhombo-mere 6 (Fig 4B6) and posterior yolk syncytial layer (Fig 4B4) At 36 hpf, hybridization signals for crabp1a mRNA were observed in the nucleus of the diencepha-lon, the ventricular zone of the developing optic tec-tum and the dorsal retina, the epidermis of the tail tip

in addition to neurohypophysis (Fig 5A,C,E) crabp1b transcripts were abundantly distributed in the posterior hindbrain and anterior spinal cord in which the signal was restricted to the dorsal spinal cord and gradually diminished along the length of the spinal cord (Fig 5B,F) The hybridization signal in the ventral part of the anterior somites, hypaxial muscles and tail tip showed the presence of crabp1b mRNA in these tissues (Fig 5B,D,F) At 48 hpf, crabp1a transcripts were detected in the nucleus of the diencephalons, optice tectum and neurohypophysis (Fig 5G,I,K), while crabp1b mRNA was most prominent in the posterior hindbrain and, to a lesser extent, in the spinal cord and ventral part of anterior myotomes (Fig 5H,J,L)

Tissue-specific distribution of crabp1a and crabp1b mRNA in adult zebrafish

The distribution of crabp1a and crabp1b transcripts in adult zebrafish tissues was analyzed by RT-PCR (Fig 6A) The crabp1a-specific primers generated RT-PCR products of the expected size only from RNA of the brain, but not from any other tissues examined including the liver, ovary, skin, intestine, heart, muscle and testis crabp1b mRNA was detected by RT-PCR

in the skin, intestine, brain and muscle of adult zebra-fish As a positive control for RT-PCR, receptor for activated C kinase gene (rack1)-specific products were generated from RNA of all the adult tissues examined

No RT-PCR products were detected in the negative control reactions that lacked reverse-transcribed cDNA templates for each of the three genes analyzed

In addition to RT-PCR, tissue section in situ hybri-dization was performed with crabp1a- and crabp1b-specific oligouncleotide probes to determine tissue-specific distribution of the crabp1 gene transcripts in adult zebrafish A hybridization signal was detected by the crabp1a-specific oligonucleotide probe in the optic tectum of the adult zebrafish brain (Fig 6B) We have previously shown that the specific distribution of the brain-type fatty acid-binding protein (fabp7a) mRNA

is localized to the pariventricular grey zone of the optic tectum of the adult zebrafish brain [24] Similar pat-terns of mRNA distribution in the optic tectum were

Fig 3 Comparison of the syntenic relationship of the zebrafish

crabp1 genes with their human ortholog The zebrafish duplicated

crabp1a and crabp1b genes have conserved syntenies (left column)

with the human CRABP1 on chromosome 15 (right column)

Ortho-logous crabp1 gene symbols are in bold Another pair of duplicated

genes (foxb1.1 and foxb1.2) on zebrafish LG 7 and LG 25 and the

human FOXB1 ortholog on chromosome 15 are underlined The

order of the human syntenic genes on human chromosome 15 was

determined based on the cytogenetic mapping data from LocusLink

(http://www.ncbi.nlm.nih.gov/locuslink) and the gene loci on the

zebrafish LGs are listed in the order appearing on the human

chromosome 15.

observed for crabp1a and fabp7a (Fig 6B) No

hybrid-ization signal was observed in the optic tectum of

tis-sue sections hybridized to a negative control, sense

oligonucleotide probe (Fig 6B) Tissue sections

hybrid-ized to an antisense oligonucleotides corresponding to

the zebrafish crabp1b mRNA did not exhibit

hybridiza-tion signal even in tissues where crabp1b mRNA had

been detected by RT-PCR (data not shown) The levels

of crabp1b transcripts may be below the level of

sensi-tivity of detection by the technique of tissue section

in situhybridization

Discussion

The differentiation and development of primary motor neurons in vertebrates is controlled by RA signaling [25] The developing posterior hindbrain [26,27], the anterior spinal cord [26–28] and the retina [26,29] are

A

B

C

Fig 4 Spatio-temporal distribution of transcripts of the zebrafish crabp1a and crabp1b genes during development (17–24 hpf) (A) The pres-ence of crabp1b mRNA in the primary neurons (arrow heads) of spinal cord (Sp) and the trigeminal placode (Tp) during middle somitogene-sis (A1) Dorsal view, head to the left; (A2) Dorsal view, head to the left; (A3) lateral view, head to the left (B) Comparison of the mRNA distribution of crabp1a and crabp1b during developmental stages of 24 hpf crabp1a mRNA was detected in the neurohypophysis (Nh) and tail bud (Tb) (B1-B3), while crabp1b mRNA was distributed in the rhombomere 7 (r7), spinal cord and hypaxial muscles (Hm) (B4-B6) Pres-ence of crabp1b mRNA in the posterior yolk synctial layer (YLS) (B4) and in the neurons of r6 and anterior spinal cord is indicated by arrow heads (B6) (C) Sequential cross sections (rostral to caudal) around the boarder of hindbrain and spinal cord showing transversal distribution

of the crabp1b mRNA in r7, neurons of spinal cord (N Sp), dorsal and ventral spinal cord (D Sp and V Sp) and the anterior somites (So) of the 24 hpf embryos.

prominent sites of RA distribution and action The

localization of crabp1b mRNA in regions of active

neurogenesis in the developing CNS of zebrafish

embryos suggests that CRABP1b may well act as a

mediator of RA action during embryonic neurogenesis

Neurogenesis in the CNS of adult teleosts is

restric-ted to specific proliferative zones The optic tectum

in fishes, birds and amphibians exhibits continuous

neurogenesis [30–32] This generation of new neurons

in the adult CNS most assuredly requires the

expres-sion a specific subset of neuronal genes One of the

genes associated with neurogenesis in both the

devel-oping and adult CNS is the brain-type fatty acid

bind-ing protein (B-FABP) gene [33–35] In adult canary,

B-FABP mRNA is distributed widely in the brain and

is abundant in cell types known or suspected to

undergo neurogenesis in the adult brain [35] In

zebra-fish, the transcripts of crabp1a (this study) and fabp7a

coding for B-FABP [24] were both localized to the

optic tectum RA and docosahexanoic acid, the ligands

for CRABPI and B-FABP, respectively, are necessary

for neurogenesis As such, crabp1a and fabp7a may be essential genes in the signaling pathways for neurogen-esis in the optic tectum

To date, only a single copy of the gene coding for CRABPI has been reported in the genomes of various vertebrate species including fishes [1,19] Based on phy-logenetic analyses and conserved synteny with human chromosome 15, we have identified duplicated copies

of the crabp1 genes, crabp1a and crabp1b, in the zebra-fish genome Furthermore, the two zebrazebra-fish crabp1 paralogs showed high amino acid sequence identity to each other, but differential spatio-temporal expression patterns during development and in adulthood In pre-vious studies, we have identified duplicated genes for several other paralogous members of the iLBP multi-gene family in the zebrafish genome, the fabp7a and fabp7b [36], rbp1a and rbp1b [37], rbp2a and rbp2b [37], crabp2a and crabp2b [38] genes It appears that duplication is common for the iLBP gene family members in zebrafish, which attests to the hypothesis

of ‘large scale gene duplication in fishes’ [21,23,39–43]

J I

D C

Fig 5 Comparison of the mRNA distribution of crabp1a and crabp1b during developmental stages of 36 (A–F) to 48 (G–L) hpf crabp1a mRNA was detected sequentially in the neurohypophysis (Nh), tail bud (Tb), diencephalons (Di), tectum (Te), retina (Re) and anterior spinal cord (Sp), while crabp1b mRNA was distributed in r7, spinal cord, hypaxial muscles (Hm), Anterior somites (So) and myotomes (My), poster-ior hind brain (Hb), the pectoral fin (Pf), tail bud and in the posterposter-ior yolk synctial layer (YLS) (A, B, G, H) Lateral view, head to the left; (E, F,

K, L) Dorsal view, head to the left; (C, D) magnified lateral view of the tail; (I, J) magnified lateral view, head to the left.

An intriguing question is how have both duplicated

copies of members of the iLBP mutigene family been

preserved in the zebrafish genome? The fate of

dupli-cated genes, in general, and the mechanism for

pre-servation of ancient duplicated genes remains unclear

Ohno [44] was the first to suggest that the fate of

duplicated genes depends on the occurrence of null

mutations, which commonly lead to gene silencing (i.e nonfunctionalization) He also suggests that some mutations may give rise to a gene with a new func-tion that is distinct from the ancestral or duplicated sister gene (i.e neofunctionalization) More recently,

it has been argued in the ‘duplication–degeneration– complementation’ (DDC) model [45,46] that subfunc-tionalization of duplicated genes accounts for the preservation of many gene duplicates owing to accu-mulation of mutations in regulatory elements Conse-quently, each copy of the duplicated gene pair shares

a subset of the ancestral functions, e.g partitioning

of tissue-specific gene expression In mammals, CRABP1 is expressed in the developing CNS and retina from an early embryonic stage [26,47–49] and

is widely distributed in adult tissues including the brain, spinal cord, liver, ovary, testis, uterus, adrenal gland and retina [1] In the present study, we observed differential patterns of crabp1a and crabp1b expression in the developing and adult zebrafish The zebrafish crabp1a transcripts were detected in regions

of the developing fore- and midbrain whereas crabp1b mRNA was detected in the developing hindbrain and spinal cord crabp1a mRNA was observed by tissue section in situ hybridization (Fig 6B) in the optic tec-tum of the adult zebrafish brain crabp1b mRNA was detected in the adult brain, muscle, intestine and skin but only by the sensitive technique of RT-PCR (Fig 6A) and not by in situ hybridization (data not shown) In addition to this spatial segregation, we observed a temporal segregation of crabp1a and crabp1b expression crabp1b mRNA was detected dur-ing early embryonic and larval development while crabp1a transcripts were only detected at later stages

of embryonic development (24 hpf and thereafter) Together, the expression patterns of the zebrafish crabp1a and crabp1b generally sum to the expression

of their mammalian orthologs in the developing ner-vous system [26,47–49] The partitioning of the tem-poral and spatial distribution of the zebrafish crabp1a and crabp1b gene transcripts during development and

in adulthood compared to their mammalian CRABP1 orthologs suggests that retention of the duplicated crabp1 genes in zebrafish is the result of sub-functionalization during evolution

Experimental procedures

Maintenance of fish Zebrafish were purchased from a local aquarium store Fish feeding, breeding and embryo manipulation was conducted according to established protocols [50]

A

B

Fig 6 Tissue-specific distribution of the zebrafish crabp1a and

crabp1b transcripts in adult zebrafish (A) Tissue-specific RT-PCR

products were generated using cDNA derived from total RNA

extracted from various adult zebrafish tissues (indicated above each

lane) using primers corresponding to the cDNA for crabp1a and

crabp1b A RT-PCR product corresponding to the constitutively

expressed rack1 mRNA coding for receptor for activated C kinase 1

was generated from RNA in all samples A negative PCR control

without cDNA template did not generate RT-PCR product (B)

Sagittal tissue sections of adult zebrafish were hybridized to

[ 32P]dATP[aP] labeled crabpIa and fabp7a gene specific

oligonucleo-tide probes (B1) Both crabp1a and fabp7a transcripts were

colocal-ized in the adult zebrafish optic tectum (arrows, B1) The control

section hybridized with a sense probe produced no signal in the

optic tectum The hybridized tissue sections were stained with

cre-syl violet and the region corresponding to the optic tectum region

is shown in panel B2 Arrows indicate the periventricular gray zone

(PGZ) of the optic tectum (OT).

Cloning of cDNAs for the zebrafish crabp1a and

crabp1b

To obtain the complete cDNA sequence encoded by the

zebrafish crabp1a and crabp1b genes, both 3¢ rapid

amplifica-tion of cDNA ends (3¢-RACE) and 5¢-RNA ligase

mediated-RACE (5¢-RLM-mediated-RACE) were employed as previously

described [51,52] The nested sense and antisense primers

used for 3¢-RACE and 5¢-RLM-RACE were designed based

on a zebrafish expressed sequence tag (EST, GenBank

acces-sion number BI533516), which had sequence similarity to the

mammalian CRABPI cDNA (crabp1a; 3¢-RACE: 5¢-CCC

AACTTCGCCGGCACCTGG-3¢, 5¢-TGAAAGCTCTCG

GCGTAAAC-3¢; 5¢-RLM-RACE: 5¢-GAGCTTTCAGA

AGTTCGTCG-3¢, 5¢-GAATCTCCACATGCGGTTTG-3¢)

and a zebrafish genomic DNA sequence assembly

(BX663612) which harbors the coding sequence of another

gene similar to the mammalian CRABPI (crabp1b; 3¢-RACE:

5¢-GCTAACAGATCAATAGGCTTC-3¢, 5¢-GATTTGAA

AGCAAGAGGGTC-3¢; 5¢-RLM-RACE: 5¢-TTAGACGC

AGCCGCACAAG-3¢, 5¢-CGGCCATCGACGGTCTC-3¢)

Three 3¢-RACE cDNA and 5¢-RLM-RACE clones of each

gene were sequenced and the complete cDNA sequences of

crabp1aand crabp1b genes were determined by aligning and

combining the sequences

Phylogenetic analysis

Phylogenetic analysis of the zebrafish crabp1a, crabp1b and

other fish and mammalian cellular retinoid-binding protein

genes was performed using clustalx [53] A bootstrap

neighbor-joining phylogenetic tree was constructed using

the zebrafish intestinal-type fatty acid-binding protein

sequence (I-FABP, GenBank accession number AY266452)

as an outgroup

Linkage mapping of crabp1a and crabp1b with

radiation hybrid panel

Radiation hybrids of the LN54 panel [22] were used to assign

the crabp1a and crabp1b genes to a specific zebrafish linkage

group The sequences of the primers used to amplify the

genomic DNA from cell hybrids of the LN54 panel are:

crabp1a: 5¢-TGGTTTGCACGCGGATTTAC-3¢, 5¢-GAAC

GATGACTACAGCAATGG-3¢; crabp1b: 5¢-GCAAATGT

GAGCACTAAGTG-3¢, 5¢-CGGCCATCGACGGTCTC-3¢

The PCR conditions have been described previously [51]

Whole mount in situ hybridization to zebrafish

embryos

To reveal the spatio-temporal distribution of the zebrafish

crabp1a and crabp1b transcripts in developing zebrafish,

whole mount in situ hybridization was performed as

des-cribed by Thisse & Thisse at the website: http://zfin.org/

zf_info/zfbook/chapt9/9.82 RNA probes complementary

to zebrafish crabp1a and crabp1b mRNAs were generated from sequenced 3¢ RACE clones

Reverse transcription-polymerase chain reaction (RT-PCR)

Conditions for RT-PCR used to determine the tissue-specific distribution of the crabp1a and crabp1b transcripts in adult zebrafish were according to those previously described in [51] Primers employed in RT-PCR were designed based

on cDNA sequences of the zebrafish crabp1a (5¢-TGAAAG CTCTCGGCGTAAAC-3¢, 5¢-GAAC GATGACTACAGC AATGG-3¢) and crabp1b (5¢-GATTTGAAAGCAAGAGG GTC-3¢, 5¢-CTGCAAGTGCTGGAATATTC-3¢) The reac-tion products were size-fracreac-tionated by agarose gel electro-phoresis

Adult zebrafish tissue section in situ hybridization

Zebrafish tissue section in situ hybridization was performed according to [52] The antisense oligonucleotide sequences complementary to the zebrafish crabp1a (5¢-CATGCAAT GAAGTTTTCTGGGTTTTCTAGACAG-3¢) and fabp7a (5¢-GTAATATCGTCAAGTTGCCAGGGTAATACTGA AACG-3¢) mRNA sequences [24] were used as in situ hybridization probes A previously synthesized sense oligo-nucleotide probe [52] was used as a negative control Following hybridization and autoradiography, the tissue sections were stained with cresyl violet

Acknowledgements

This work was supported by a research grant from the Natural Sciences and Engineering Research Council of Canada (to JMW), the Canadian Institutes of Health Research (to ED-W), the Institut National de la Sante´

et de la Recherche Me´dicale, Centre National de la Recherche Scientifique, Hoˆpital Universitaire de Stras-bourg, Association pour la Recherche sur le Cancer, Ligue Nationale Contre le Cancer, National Institute

of Health (to CT and BT), and Izaak Walton Killam Memorial Scholarships (to R-ZL and MKS) We thank Marc Ekker for the DNA from LN 54 radiation hybrid panel for linkage mapping We also thank Violaine Alunni, Aline Lux, Vincent Heyer and Agnes Degrave for help during the experimental stages of this work

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