Báo cáo khoa học: Cellular retinol-binding protein type II (CRBPII) in adult zebrafish (Danio rerio) cDNA sequence, tissue-specific expression and gene linkage analysis pptx

Cellular retinol-binding protein type II CRBPII in adult zebrafishcDNA sequence, tissue-specific expression and gene linkage analysis Marianne C.. Wright1 1 Department of Biology, and 2

Cellular retinol-binding protein type II (CRBPII) in adult zebrafish

cDNA sequence, tissue-specific expression and gene linkage analysis

Marianne C Cameron1, Eileen M Denovan-Wright2, Mukesh K Sharma1and Jonathan M Wright1

1 Department of Biology, and 2 Department of Pharmacology, Dalhousie University, Halifax, Nova Scotia, Canada

We have determined the nucleotide sequence of a zebrafish

cDNA clone that codes for a cellular retinol-binding protein

type II (CRBPII) Radiation hybrid mapping revealed that

the zebrafish and human CRBPII genes are located in

syntenic groups In situ hybridization and emulsion

autora-diography localized the CRBPII mRNA to the intestine and

the liver of adult zebrafish CRBPII and intestinal fatty acid

binding protein (I-FABP) mRNA was colocalized to the

same regions along the anterior-posterior gradient of the

zebrafish intestine Similarly, CRBPII and I-FABP mRNA

are colocalized in mammalian and chicken intestine

CRBPII mRNA, but not I-FABP mRNA, was detected in

adult zebrafish liver which is in contrast to mammals where

liver CRBPII mRNA levels are high during development but

rapidly decrease to very low or undetectable levels following

birth CRBPII and I-FABP gene expression appears

there-fore to be co-ordinately regulated in the zebrafish intestine as has been suggested for mammals and chicken, but CRBPII gene expression is markedly different in the liver of adult zebrafish compared to the livers of mammals As such, retinol metabolism in zebrafish may differ from that of mammals and require continued production of CRBPII in adult liver The primary sequence of the coding regions of fish and mammalian CRBPII genes, their relative chromo-somal location in syntenic groups and possibly portions of the control regions involved in regulation of CRBPII gene expression in the intestine appear therefore to have been conserved for more than 400 million years

Keywords: Danio rerio; fatty acid binding protein; cellular retinol binding protein; tissue-specific expression; retinol metabolism

Cellular retinol-binding proteins (CRBPs) are members of

the intracellular lipid-binding protein family which includes

the retinoic acid (CRABP) and fatty acid (FABP) binding

proteins This family consists of low molecular mass ( 14–

16 kDa) polypeptides that bind and transport retinoids,

fatty acids, and bile salts [1,2] Members of this protein

superfamily have a common three dimensional shape

described as a clamshell structure composed of two

orthogonal b-sheets, each consisting of five antiparallel

b-strands and two a-helices [3] Hydrophobic ligands are

held in the central cavity of the bivalve-like polypeptide

The three CRBPs, type I, II, and III, are named according

to the order in which they were discovered in mammals

Their putative role in cell physiology is in the metabolism of

retinol (vitamin A) Retinol and its derivates are important

for vision, reproduction, metabolism, cellular differentiation

and pattern formation during embryogenesis [4] After absorption in the mammalian intestine, the enzyme b-carotene dioxygenase catalyzes the oxidative cleavage of b-carotene to retinal Retinal is reduced to retinol by the enzyme retinal dehydrogenase Retinol is then esterified by the microsomal enzyme lecithin:retinal acyltransferase (LRAT) to retinoic acid and packaged into chylomicrons for subsequent uptake by the liver CRBPI and II bind retinal and retinol whereas CRBPIII binds retinol, but not retinal [4–7] CRABPs bind and transport retinoic acid [4,5,7] The CRBPs are thought to participate in ligand binding and regulate the metabolism of retinal and retinol while protecting the CRBP-bound ligands from nonspecific reactions [8] Biochemical studies have shown that CRBPII-bound retinol serves as a substrate for the enzyme, LRAT, implicating CRBPII as a component in directing and channeling dietary retinol to nascent chylomicroms Direct evidence for the role of CRBPI in vitamin A metabolism has been provided by transgenic knockout studies which demonstrated that CRBPI knockout mice are phenotypi-cally normal when fed a vitamin A-enriched diet, but when the diet is deficient in vitamin A, stores of retinyl esters are depleted over 5 months and the mice develop abnormalities consistent with postnatal hypovitaminosis A [9] To date, there are no reports of CRBPII and CRBPIII gene knockouts and therefore direct evidence for their function

in vitamin A metabolism remains speculative CRBPII is restricted to the small intestine of adult rat [10], human [11], chicken [12,13] and pig [14] Studies have shown that the small intestine has the highest levels of CRBPII mRNA in

Correspondence to J M Wright, Department of Biology,

Dalhousie University, Halifax, Nova Scotia, Canada B3H.

Fax: + 902 494 3736, Tel.: + 902 494 6468,

E-mail: jmwright@dal.ca

Abbreviations: FABP, fatty acid binding protein; cDNA,

comple-mentary DNA; CRBP, cellular retinol-binding protein; EST,

expressed sequence tag; LG, linkage group; LRAT, lecithin:retinal

acyltransferase; rbp2, zebrafish retinol binding protein 2 gene;

RBP2, human retinol binding protein2 cellular gene.

Note: web site available at http://is.dal.ca/biology2/index.html

(Received 8 April 2002, revised 5 July 2002, accepted 5 August 2002)

adult rats, with undetectable or low levels of CRBPII

mRNA in other tissues [4,5] Presumably, CRBPII is

directly involved in the intestinal uptake and binding of

retinol based on calculated rates of retinol uptake in a

human intestinal cell culture model [15]

Members of the intracellular lipid-binding protein

super-family are derived from at least 14 gene duplications [16]

Prior to the vertebrate/invertebrate split, the liver/intestinal/

ileal FABP and heart/adipose/mylein FABP clades diverged

approximately 700 million years ago It has been suggested

that the CRBP genes diverged from the liver/intestinal/ileal

FABP clade about 500 million years ago The mammalian

CRBPI and CRBPII genes presumably arose by gene

duplication sometime after the divergence of amphibia from

mammals as a single copy of the CRBP gene is found in

Xenopus[17] An alternative explaination, however, is that

one of the duplicated copies of the CRBP gene may have

been lost in the amphibian lineage

The structure and function of fatty acid and

retinoid-binding proteins have been studied extensively in mammals,

but only superficially in other taxa such as the teleost fishes

Vitamin A and its derivates are clearly important mediators

of normal vertebrate development [4,8,9] As zebrafish is

promoted as a model experimental system for study of

vertebrate development, an understanding of the function of

CRBPs in vitamin A metabolism during zebrafish

embryo-genesis would be of interest to developmental biologists

Moreover, comparative studies of CRBP gene expression in

fishes and mammals may provide insight into the role(s) of

these intracellular retinol- and retinal-binding proteins in

vitamin A metabolism As part of ongoing studies in our laboratories on the evolution, tissue-specific expression and gene regulation of members of the intracellular lipid-binding protein family in zebrafish [18–20], we have determined the nucleotide sequence of a cDNA clone and deduced the amino-acid sequence for a zebrafish CRBPII Furthermore,

we report the tissue-specific distribution of the CRBPII mRNA in adult zebrafish and assignment of the CRBPII gene to linkage group 15 in the zebrafish genome

M A T E R I A L S A N D M E T H O D S

Searches of the zebrafish EST database in GenBank identified a cDNA clone (GenBank accession number AI544932) that was similar to the 5¢ end of the rat cellular retinol-binding protein type II This clone (fb69e02.y1) was purchased from Incyte Genomics Inc and the complete nucleotide sequence was determined [18] The deduced amino-acid sequence of the cDNA sequence was aligned with other intracellular lipid-binding protein sequences in GenBank usingCLUSTALW[21] and an output of percentage sequence identity generated

DNA from the LN54 radiation hybrid panel [22] (zebrafish DNA in a mouse background) was used

as template in PCR reactions to assign the linkage group for the CRBPII gene in the zebrafish genome (see Fig 1 for primer location) PCR reactions contained 1X PCR buffer (MBI Fermentas), 1.5 mM MgCl2, 0.4 lM sense primer (5¢-TTCGCCACCCGTAAGATC-3¢), 0.4 lM antisense primer (5¢-AAACTCCTCTCCAATGACG-3¢), 0.2 mM

Fig 1 Nucleotide sequence of a cDNA clone coding for a zebrafish CRBPII The complete nucleotide sequence of the EST clone fb69e02.y1 was determined (GenBank accession number AF363957) The 549 bp sequence contained an open-reading frame of 405 nucleotides coding for a protein

of 135 amino acids The predicted amino-acid sequence of the zebrafish cDNA clone was most similar to mammalian CRBPIIs (see Fig 2) The sequence complementary to the antisense oligonucleotide probe used for in situ hybridization analysis is underlined and in bold font The position of the nucleotides corresponding to the 5¢ or complimentary to the 3¢ primers used for PCR amplification of the CRBPII cDNA probe used for Northern blot and radiation hybrid linkage mapping analysis are boxed and numbered Ô1Õ and Ô2Õ, respectively The polyadenylation signal sequence, AATAAA, is italicized and in bold font.

dNTPs, 1.25 U Taq DNA polymerase and 100 ng of hybrid

cell DNA Control reactions contained 100 ng of either

zebrafish or mouse parental cell line DNA or a 1 : 10

mixture of zebrafish and mouse parental cell line DNA

PCR conditions were 94C for 4 min followed by 32 cycles

of 94C for 30 s, 60 C for 30 s, 72 C for 30 s and a final

extension at 72C for 7 min Products were separated by

agarose gel electrophoresis and the radiation hybrid panel

was scored and then analyzed according to the directions at

(http://mgcdh1.nichd.nih.gov:8000/zfrh/beta.cgi)

PCR primers (5¢-CCAGCACATCCAGCTTC-3¢) and

(5¢-GCCTGTTTGGAGCATTAG-3¢) (see Fig 1 for

pri-mer location) were used to amplify a 442-bp product from

DNA of clone fb69e02.y1 This product was used as a

hybridization probe for Northern blot analysis [23] The size

of the hybridizing mRNA was determined by comparing its

electrophoretic mobility with molecular mass markers

(0.24–9.5 kB RNA ladder, Gibco BRL)

In situhybridization was performed using an antisense

oligonucleotide probe (see Fig 1) to determine the pattern

of CRBPII expression in adult zebrafish Based onBLASTN

searches of GenBank, the in situ hybridization probe did

not exhibit significant sequence similarity to any other

DNA sequence currently available in GenBank Fourteen

micrometer transverse, sagittal, and coronal sections of

adult zebrafish were hybridized to DNA probes using

previously described methods [24] Following hybridization

and post-hybridization washes, the sections were exposed

to autoradiographic film Emulsion autoradiography of the

tissue sections that hybridized to the CRBPII antisense

probe was performed to localize the in situ hybridization

signal to the cellular level [24] A hybridization probe

corresponding to the sense strand of a portion of a

zebrafish I-FABP mRNA, shown previously not to

hybridize to any transcript in total zebrafish RNA [18],

was used as a negative control for in situ hybridization

studies A probe complementaty to the coding strand of

the zebrafish I-FABP mRNA [18] was used as a positive

control for in situ hybridization and emulsion

autoradio-graphy Following emulsion autoradiography, the sections

were stained with cresyl violet and viewed under

bright-field and dark-bright-field illumination [24]

R E S U L T S A N D D I S C U S S I O N

The nucleotide sequence of a zebrafish EST clone reported

in GenBank to have sequence similarity to the 5¢ end of

CRBPII cDNAs from mammals and chicken was

deter-mined (Fig 1) Sequence from forward and reverse

sequen-cing reactions was aligned and discrepancies were resolved

by examination of the primary sequence data The complete

sequence (GenBank accession number AF363957),

deter-mined from both strands, differed from that of the partial

sequence of the EST clone reported in GenBank (accession

number AI544932) at several positions The cDNA

sequence contained an open-reading frame of 405 bp

encoding a protein of 135 amino acids The percentage

amino-acid sequence similarity between the open-reading

encoded by the cDNA clone and the amino-acid sequences

of intracellular lipid-binding proteins from zebrafish and

other species indicate that the cDNA clone codes for the

zebrafish CRBPII (Fig 2) The zebrafish CRBPII protein

was one amino acid longer than mammalian CRBPII and

equal in length to chicken CRBPII The molecular mass of the CRBPII protein in zebrafish, based on the predicted amino-acid sequence, is 15.8 kDa The molecular mass of this zebrafish CRBPII is comparable to other members of the intracellular lipid-binding protein family which are all between 14 and 16 kDa [1,2] The zebrafish CRBPII amino-acid sequence is most similar to the chicken CRBPII (76% identity) The zebrafish CRBPII amino-acid sequence exhibits 73–75% sequence similarity to mammalian CRBPIIs and less than 40% amino-acid sequence identity

to other intracellular lipid-binding proteins

Cheng et al [25] proposed that Arg106 and Arg126 present in some members of the lipid-binding protein family correspond to Gln109 and Gln129 in CRBPI and CRBPII While all FABPs and CRBPs studied to date have the same tertiary structure, the amino-acid residues at positions 109 and 129 may determine ligand-binding specificity Both Gln residues are found in the zebrafish CRBPII sequence at the comparable positions within the amino-acid alignment of other intracellular lipid-binding proteins (Fig 2) Gln109 is not strictly conserved in all CRBPs, however, as the chicken CRBPII and mouse CRBPIII have a histidine residue at this position

Phylogenetic analyses of 51 intracellular lipid-binding proteins, from vertebrates and invertebrates, indicate that at least 14 gene duplications have occurred during the evolution of this multigene family [16] As the amino-acid sequence of the zebrafish CRBPII reported here is most similar to CRBPIIs from other species, and not to CRBPI

or other intracellular lipid-binding proteins from zebrafish (Fig 2), the duplication of the ancestral CRBP gene that gave rise to the CRBPI and CRBPII genes most likely occurred before the divergence of the teleost fishes and mammals, approximately 400 mya We have shown that the CRBPI gene exists in the zebrafish genome (M.K Sharma

& J.M Wright, unpublished data) The mammalian CRBPI and CRBPII genes are linked on chromosome 9 in mouse and 3 in humans and share sequence similarity including the conserved Gln residues at positions 109 and 129 [25,26] Radiation hybrid mapping studies [22] assigned the CRBPII gene to linkage group 15 (LOD score 19.8) in the zebrafish genome (Primary data and the RH vector for linkage analysis is available upon request to the corresponding author) The CRBPII gene is flanked by the growth associated protein 43 (GAP 43) gene on one side and the chordin (CHRD) gene on the other in both zebrafish and in human (Table 1) This synteny suggests that a common linkage group was inherited from the ancestor of fishes and mammals In mouse, however, the synteny has not been maintained as CRBPII is located on chromosome 9, while GAP 43 and CHRD are located on chromosome 16 (Table 1) This suggests a translocation/rearrangement of this region of the mouse genome after the divergence of fishes and mammals The conservation of amino-acid sequence among all CRBPIIs and the evidence that zebrafish and human CRBPII genes are in the same syntenic group suggest that fish and mammals share a common ancestral CRBPII gene

Northern blot-hybridization of the zebrafish CRBPII cDNA to total RNA extracted from whole adult zebrafish detected a single mRNA transcript of  720 nucleotides (Fig 3A) The difference in size between the mRNA transcript detected by Northern blot ( 720 nucleotides)

and the size of the cDNA sequence (549 nucleotides) suggests

that the cDNA clone is probably lacking the complete poly A

tail or part of the 5¢ untranslated region, or both

In situ hybridization analysis of adult zebrafish tissue

sections revealed that the hybridization signal resulting from

the specific annealing of the CRBPII antisense probe was

confined to the intestine and, at relatively lower levels, to the

zebrafish liver (Fig 3B,C) Hybridization of the

CRBPII-specific probe to the intestine is most evident in the

transverse (Fig 3B) and coronal (Fig 3C) sections while

hybridization to the liver is more clearly seen in the coronal

sections (Fig 3C) The radiolabel associated with the layer

beneath the external skin appears to be non–specific

interaction of the probe with this tissue as it is seen in all

autoradiograms regardless of the hybridization probe

employed, i.e the CRBPII or I-FABP antisense probes or

the I-FABP negative control sense probe (Figs 3B,C) The hybridization signal resulting from the specific annealing of the I-FABP antisense probe was confined to the intestine as previously reported [18]

As CRBPII and I-FABP mRNA have been colocalized in the mammalian and chicken proximal portion of the small intestine [27–29], we examined the distribution of CRBPII and I-FABP mRNA in adjacent tissue sections of adult zebrafish Emulsion autoradiography of tissue sections that hybridized to the CRBPII and I-FABP antisense and negative control I-FABP sense probes was performed to localize the hybridization signal at the cellular level The CRBPII mRNA was localized to the enterocytes in the microvilli of the intestine and to the hepatocytes of the liver (Fig 4A,B) The I-FABP mRNA was similarly localized to the enterocytes of the intestine, but was not detected in the

Fig 2 Amino-acid sequence alignment of zebrafish CRBPII with other CRBPs, CRABPs, and FABPs The amino-acid sequences of zebrafish CRBPII (ZbfshCRBPII; GenBank Accession number AF363957), chicken CRBPII (ChickCRBPII [43]), pig CRBPII (PigCRBPII; P50121), human CRBPII (HumanCRBPII; AAC50162), rat CRBPII (RatCRBPII; P06768), mouse CRBPIII (MouseCRBPIII; AA466092), rat CRBPI (RatCRBPI; P02696), rat CRABPII (RatCRABPII; P51673), human CRABPI (HumanCRABPI; P29762), zebrafish brain FABP (ZbfBFABP; Af237712), and zebrafish intestinal FABP (ZbfIFABP; AF180921) were aligned using CLUSTALW [21] Dashes, indicating addition/deletion dif-ferences between the zebrafish CRBPII and other amino-acid sequences, were added to maximize alignment Dots indicate identity between the amino-acid sequence of zebrafish CRBPII and other CRBPs, CRABPs and FABPs The percentage amino-acid sequence similarity relative to the zebrafish CRBPII is indicated at the end of each sequence.

Table 1 Zebrafish-human conserved syntenies.

Accession

Chromosomal

Chromosomal location

a Wood et al [45]; b LocusLink (http://www.ncbi.nlm.nih.gov/LocusLink/list.cgi), NCBI.

liver (Fig 4A,B) [18] In the transverse sections, the

positional difference of CRBPII mRNA demarcates the

anterior and posterior parts of the intestine (Fig 4A) In

adjacent sections, the distribution of I-FABP-specific

hybridization signal was the same as that observed for

CRBPII (Fig 4A) Due to the entwined positioning of the

intestine within the zebrafish, the coronal sections display

three cross-sections corresponding to different regions of the intestine (Fig 4B) There was hybridization to only two of the three cross sections of the intestine for the CRBPII antisense and I-FABP antisense probes The radiolabel associated with the centre of the intestine is present in all sections labeled with antisense and sense oligonucleotides indicating nonspecific binding of the probes to the contents

of the gut Evidence of I-FABP mRNA restricted to just the anterior of the zebrafish intestine was not previously observed by us possibly owing to the limited sections assayed [18] It is possible that subtle differences in the amount of CRBPII and I-FABP mRNA exist along the anterior-posterior of the intestine that are not detectable using in situ hybridization and emulsion autoradiography Moreover, using whole-mount in situ hybridization to zebrafish embryos, it was previously determined that I-FABP mRNA is first expressed in the intestinal tube 3 days postfertilization and, by 5 days postfertilization and on-ward, I-FABP mRNA is abundant in the anterior intestine but is not detectable in the posterior intestine [27]

In adult mammals, CRBPII mRNA levels gradually decrease along the anterior-posterior axis of the intestine [28,29] The proximal intestine of mammals has a higher capacity to absorb retinol than does the distal portion [30,31] Levin et al [15] demonstrated that CRBPs are directly involved in retinol absorption in a human intestinal cell line and that the amount of CRBPI and CRBPII mRNA and protein is directly related to the rate of retinol absorption It is believed that CRBPII directs retinal and retinol to the enzymes, retinal dehydrogenase and LRAT, respectively, in the intestine CRBPII, microsomal retinal reductase and LRAT are colocalized in the mammalian intestine [32–34] The CRBPII gradient in the intestine parallels the change in enzyme activity of LRAT and retinal reductase which is greater in the anterior than in the posterior of the intestine [34] Thus, these findings are consistent with the proposed role of CRBPII in retinol metabolism Similarly, previous studies in mammals have shown that there is a gradient of I-FABP expression along the horizontal axis as concentrations of I-FABP mRNA and proteins gradually decrease from high levels in the jejunum to negligible levels in the colon [35–38] CRBPII and I-FABP expression is similar along the anterior-posterior axis in the intestine of mammals Therefore, a corresponding trend for CRBPII and I-FABP expression in zebrafish is consistent with their expression in mammals The abrupt termination of CRBPII expression along the anterior-posterior axis of the zebrafish intestine, however, contrasts with the gradual decrease in CRBPII and I-FABP expression pattern in mammals

In the 5¢-control regions of the mammalian CRBPII [39] and I-FABP [35] genes, a closely related cis-element that consists of nearly perfect tandem repeats, termed retinoid x response element (RXRE) [40] has been found It is conceivable therefore that these two genes may both be regulated by the action of retinoid x receptor (RXR) binding to RXRE [41] The similar distribution of CRBPII and I-FABP mRNA in the zebrafish intestine reported here may reflect the co-ordinate regulation of these genes by common intestinal transcriptional factors in zebrafish

In addition to being abundant in intestine, CRBPII is found in neonatal liver hepatocytes of the rat and chick [10,42] In rat, however, the levels of CRBPII mRNA in the

Fig 3 CRBPII mRNA expression in the adult zebrafish The complete

coding sequence of the zebrafish CRBPII cDNA clone was amplified

by PCR and used as a hybridization probe in Northern blot analysis of

total cellular RNA isolated from adult zebrafish (A) The zebrafish

CRBPII-specific probe hybridized to a transcript of approximately 720

nucleotides The1.35 kb (upper line) and 0.24 kb (lower line) RNA

molecular mass markers are shown on the left of the panel In situ

hybridization analysis was performed using a 3¢ end-labelled

oligo-nucleotide complementary to an internal portion of the zebrafish

CRBPII coding region (see Fig 1) In situ hybridization of adjacent

transverse (B) and coronal (C) sections of adult zebrafish to the the

zebrafish CRBPII-specific and I-FABP-specific antisense probes are

shown An oligonucleotide corresponding to the sense strand of the

I-FABP coding region was included as a negative control This probe

was previously shown to bind nonspecifically to adult zebrafish

sec-tions in in situ hybridization analysis [18] Labelled arrows point to the

intestine (I) and liver (L) of the zebrafish The hybridization signal

resulting from the annealing of the CRBPII- and I-FABP-specific

probes are intense in the intestine A lower intensity of hybridization of

the CRBPII-, but not the I-FABP-specific probes, was seen in the

zebrafish liver.

liver decrease after birth and are undetectable in the adult

liver [10] In adult chicken, CRBPII mRNA is abundant in

the intestine but is not detected in liver [43] As stated above,

it is thought that CRBPII directs retinal to the enzyme

retinal dehydrogenase in the mammalian perinatal liver [42]

Takase et al [42] have suggested that following birth, the

absorptive cells of the intestine may be functionally

immature and unable to convert b-carotene to retinal

b-carotene is transferred to the liver in neonatal mammals

and converted to retinal by the enzyme b-carotene

dioxyg-enase in hepatocytes Later, the intestine matures and can

convert b-carotene to retinal High levels of hepatic CRBPII

are then no longer necessary for the production of retinol

and CRBPII levels decrease in adult liver Chicken and rat

are known to convert most ingested b-carotene to retinal

and then to retinol in enterocytes such that lower levels of

b-carotene and retinal are found in their circulation

compared to the levels observed in humans [44] These

findings suggest that hepatic CRBPII may play a role in

metabolizing hepatic b-carotene to retinal and the

subse-quent esterification of the converted retinol only during the

perinatal period in mammals [42] The in situ hybridization

and autoradiographic emulsion studies show that CRBPII

mRNA is abundant in the liver of adult zebrafish (Fig 4)

This pattern of CRBPII expression therefore differs

mark-edly from that observed in rat and chicken [10,42] Retinol

metabolism of fishes may differ from that of mammals and

chicken in that large amounts of b-carotene continue to be

transported to the adult liver of teleost fishes resulting in the

need for high levels of CRBPII mRNA observed in the liver

of adult zebrafish

CRBPII and I-FABP mRNA are colocalized in the fish and mammalian intestine and may be co-ordinately regu-lated by RXR acting at RXRE within the control regions of these genes The differential expression of CRBPII and I-FABP in the adult zebrafish liver, however, suggests that other transcription factors may regulate CRBPII gene expression in the livers of adult zebrafish

In summary, the zebrafish CRBPII cDNA reported here has sequence similarity to CRBPs isolated from mammals The patterns of gene expression for CRBPII and I-FABP in fishes and mammals suggest that there is co-ordinate regulation of these genes in the intestine, but not in the liver This may reflect differences in retinol metabolism between adult teleost fishes and mammals

A C K N O W L E D G E M E N T S

We wish to thank Dr Marc Ekker for providing DNA samples from the LN54 collection of radiation hybrids This work was supported by a grant from the Natural Sciences and Engineering Research Council of Canada to J M W and a grant from the Canadian Institutes of Health Research to E M D-W M C C was the recipient of a Natural Sciences and Engineering Research Council Undergraduate Student Research Award and M K S was the recipient of an Izaak Walton Killiam Memorial scholarship.

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Fig 4 Autoradiograhpic emulsion of zebrafish sections hybridized to the CRBPII- and I-FABP-specific antisense and negative control I-FABPsense probes Transverse (A) and coronal (B) zebrafish sections were hybridized

to the I-FABP, CRBPII and negative control probes and directly exposed to autoradio-graphic emulsion Following development of the emulsion, the sections were counterstained with cresyl violet and viewed under brightfield (BF) and darkfield (DF) illumination at 10· magnification The intestine (I), liver (L) and pancreas (P) are indicated The white granules viewed under darkfield illumination corres-ponded to the location of either the CRBPII

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