Growth hormone regulates the expression of hepatocyte nuclear factor-3 gamma and other liver-enriched transcription factors in the bovine liver

doi:10.1677/joe.1.05821

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Growth hormone regulates the expression of hepatocyte nuclear factor-3 gamma and other liver-enriched transcription factors in the bovine liver

S Eleswarapu and H Jiang

Department of Animal and Poultry Sciences, Virginia Polytechnic Institute and State University, Blacksburg, Virginia 24061, USA

(Requests for offprints should be addressed to H Jiang; Email: hojiang{at}vt.edu)

Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Growth hormone (GH) regulates the expression of many genes inthe liver, and for some genes this regulation may be mediatedthrough liver-enriched transcription factors (LETFs). As partof the long-term goal to investigate the role of LETFs in GHregulation of gene expression in the liver, in this study wedetermined the effect of GH administration on the expressionof 10 LETFs, including hepatocyte nuclear factor (HNF)-1 ${alpha}$ , HNF-1ß,HNF-3 ${alpha}$ , HNF-3ß, HNF-3 ${gamma}$ , HNF-4 ${alpha}$ , HNF-6, CCAAT/enhancer-bindingprotein (C/EBP) ${alpha}$ , C/EBPß, and albumin D-element bindingprotein (DBP) in the bovine liver. Eighteen non-lactating andnon-pregnant Angus cows were assigned randomly to three groups(n=6 per group) and each cow received a single intramuscularinjection of 500 mg slow-release recombinant bovine GH. Liverbiopsy samples were taken from group 1 cows 6 h after GH administration,from group 2 cows 24 h after GH administration, and from group3 cows 1 week after GH administration. Liver biopsies were alsocollected from group 3 cows 1 day before GH administration,serving as pre-GH controls. The LETF mRNAs in these liver sampleswere quantified using ribonuclease protection assays with probesgenerated from bovine LETF cDNAs cloned by standard reversetranscription–polymerase chain reaction. The levels ofHNF-3 ${gamma}$ and HNF-6 mRNAs were higher (P< 0.05) in the cows 24h and 1 week after GH administration than in the untreated cowsor the cows 6 h after GH administration. The levels of HNF-4 ${alpha}$ mRNA were higher (P< 0.05) in the cows 1 week after GH administrationthan in the other three groups of cows. The levels of C/EBP ${alpha}$ mRNA were higher (P< 0.05) in the cows 24 h after GH administrationthan in the untreated cows or the cows 6 h after GH administration.The levels of HNF-3 ${alpha}$ mRNA were higher (P< 0.05) in the cows6 h after GH administration but were lower (P< 0.05) in thecows 24 h or 1 week after GH administration compared with thosein the untreated cows. The levels of DBP mRNA were higher (P<0.05) in the cows 6 h after GH administration but were lower(P< 0.05) in the cows 24 h after GH administration comparedwith those in the untreated cows. The levels of HNF-1 ${alpha}$ , HNF-3 ${alpha}$ ,and C/EBPß mRNAs were not different (P>0.05) betweengroups. The expression of HNF-1ß mRNA was not detectable.Thus, the expression of six LETFs including HNF-3 ${gamma}$ , HNF-3ß,HNF-4 ${alpha}$ , HNF-6, C/EBP ${alpha}$ , and DBP mRNAs in the bovine liver is regulatedby GH, and these six LETFs may play a role in mediating GH regulationof gene expression in the liver. Among the 10 LETFs, the responseof HNF-3 ${gamma}$ to GH is most significant. Cloning and sequencing thepromoter region of this gene revealed multiple putative bindingelements for signal transducers and activators of transcription5 (STAT5), suggesting that GH regulation of HNF-3 ${gamma}$ expressionin the liver may be mediated through direct binding of STAT5to the HNF-3 ${gamma}$ promoter.

Introduction

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Growth hormone (GH) is a pituitary polypeptide hormone thatplays a central role in animal growth and metabolism (Harvey et al. 1995).A major target organ of GH is the liver, whereGH regulates the expression of many genes. Earlier gene expressionstudies using Northern blots showed that GH regulated the expressionof insulin-like growth factor-I (IGF-I) (Mathews et al. 1986),IGF binding protein (IGFBP)-1 (Seneviratne et al. 1990), IGFBP-3(Lemmey et al. 1997), the acid labile subunit (ALS) of the IGFbinding complex (Ooi et al. 1997), serine protease inhibitor(Spi) 2.1 (Yoon et al. 1990), suppressors of cytokine signaling(SOCS) genes (Tollet-Egnell et al. 1999), phosphoenol pyruvatekinase C and glucose transporter GLUT-2 (Valera et al. 1993),as well as the transcription factors c-fos and c-jun (Gronowski & Rotwein 1995).More recent gene expression studies employingthe microarray technology have identified many more GH-regulatedgenes in the liver. A gene expression analysis with a cDNA arraycontaining 588 rat cDNAs identified eight novel transcriptsfrom the rat liver that were regulated by GH (Thompson et al. 2000).Using a cDNA microarray representing 3000 rat sequences,Flores-Morales et al.(2001) found that 58 of 720 detectablemRNAs were regulated by GH in the rat liver, many of which werenot previously known to be GH responsive. Using a microarraycontaining 11 000 rat expression sequence tags (ESTs), Olsson et al.(2003)identified 58 metabolic genes (i.e. genes involvedin metabolism) whose expression in the liver was altered byoverexpressed bovine GH in transgenic mice. Using a microarrayconsisting of 5889 unique rat genes, Ahluwalia et al.(2004)identified 27 female- and 44 male-predominant genes that wereregulated by GH in the rat liver. These GH-regulated genes areinvolved in metabolism, detoxification, growth control and otherfunctions of the liver (Thompson et al. 2000, Flores-Morales et al. 2001,Olsson et al. 2003, Ahluwalia et al. 2004). Thus,regulation of gene expression appears to be a major mechanismby which GH affects the function of the liver.

The signaling pathways by which GH regulates gene expressionin the liver are only beginning to be understood (Herrington & Carter-Su 2001,Schwartz et al. 2002), including the identificationof the signal transducers and activators of transcription (STAT),especially STAT5B and STAT5A, as key transcription factors mediatingGH regulation of the expression of Spi 2.1 (Bergad et al. 1995),IGF-I (Woelfle et al. 2003) and several other members of theGH/IGF axis in the liver (Davey et al. 1999, Woelfle & Rotwein 2004).However, for most of the GH-regulated genes, the signalingpathways and the transcription factors involved remain to beelucidated. The expression of thousands of genes in the liveris directly or indirectly controlled by liver-enriched transcriptionfactors (LETFs), including hepatocyte nuclear factor (HNF)-1 ${alpha}$ ,HNF-1ß, HNF-3 ${alpha}$ , HNF-3ß, HNF-3 ${gamma}$ , HNF-4 ${alpha}$ , HNF-6,albumin D-element binding protein (DBP), and CCAAT/enhancer-bindingproteins (C/EBP) ${alpha}$ and C/EBPß (Schrem et al. 2002, Odom et al. 2004).Thus, GH regulation of gene expression of at leastsome genes in the liver may be mediated through LETFs. Supportingthe involvement of LETFs in GH regulation of gene expressionin the liver are recent demonstrations that C/EBPßcontributes to GH regulation of c-fos expression (Liao et al. 1999),HNF-3ß contributes to GH regulation of cytochromeP450 (CYP) 2A2, CYP4A2 and CYP2C11 expression (Park & Waxman 2001),and that HNF-3, HNF-4 and HNF-6 contribute to GH regulationof CYP2C12 expression (Sasaki et al. 1999, Delesque-Touchard et al. 2000)in the liver.

To identify LETFs that might be involved in GH regulation ofgene expression in the liver of cattle, in this study we havedetermined the effect of administration of GH on the expressionof 10 LETFs in the bovine liver.

Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Animal experiments

A total of 18 non-lactating and non-pregnant Angus beef cowswere used in this study. Each cow had free access to grass andwater. The cows were randomly assigned to three groups (groups1, 2, and 3) with each group containing six cows. Each cow receiveda single intramuscular injection of 500 mg recombinant bovineGH in a slow-release formula (Monsanto Company, St Louis, MO,USA). Liver biopsy samples were taken from group 1 cows 6 hafter GH administration, from group 2 cows 24 h after GH injection,and from group 3 cows 1 week after GH administration. Liverbiopsy samples were also taken from group 3 cows 1 day beforeGH administration, serving as pre-GH controls.

The liver biopsy was performed as described before (Oxender et al. 1971).Briefly, the skin area between the 11th and 12thribs was washed, sterilized with 70% ethanol, shaved, and 10ml lidocaine were administered subcutaneously. A small incisionwas made between the 11th and 12th ribs and the biopsy needle(Sontec Instruments, Inc., Englewood, CO, USA) was introducedto the liver through the skin incision. A liver sample of 100–300mg was collected from each cow. Once taken, liver samples wereimmediately frozen in liquid nitrogen and stored at –80°C. The animal-related procedures were approved by the VirginiaTech Animal Care Committee.

RNA and DNA extraction

Total RNA from liver tissue samples was isolated by using TRIreagent (MRC, Cincinnati, OH, USA) and poly(A) RNA was isolatedfrom total RNA using the Oligotex mRNA kit (Qiagen, Chatsworth,CA, USA), according to the manufacturers’ instructions.Genomic DNA from bovine liver tissue was isolated by standardproteinase K digestion followed by phenol–chloroform extraction.The concentration and quality of extracted RNA and DNA weredetermined by spectrometry and gel-electrophoresis respectively.

Reverse transcription–polymerase chain reaction (RT-PCR) and PCR

The RT-PCR was used to clone the cDNA fragments for nine bovineLETFs, including HNF-1 ${alpha}$ , HNF-1ß, HNF-3 ${alpha}$ , HNF-3ß,HNF-3 ${gamma}$ , HNF-6, C/EBP ${alpha}$ , C/EBPß, and DBP. The reversetranscription (total volume 20 µl), containing 2 µgbovine liver mRNA, 1 µg oligo (dT) primer or 0.5 µgrandom hexamer primers (Promega, Madison, WI, USA), 0.01 M dithiothreitol,0.5 mM deoxyribonucleotide triphosphates (dNTP) (Invitrogen,Carlsbad, CA, USA), 200 U SuperScript II reverse transcriptase(Invitrogen) and 4 µl 5x reverse transcription buffer(Promega), was performed at 42 °C for 2 h. For the PCR amplificationof each bovine LETF cDNA, 2 µl of the reverse transcriptionproducts were mixed with 12.5 µl 2x PCR master mix (Promega)and 10 pmol LETF-specific forward and reverse primers (Table1), which were designed based on the mRNA sequences of the human,ovine, or rodent LETFs, in a total volume of 25 µl. ThePCR amplification was initiated by heating at 94 °C for3 min, followed by 35 cycles of 30 s at 94°C, 1 min at 60°C (for C/EBPß and DBP) or 55 °C (for otherLETFs), and 1 min at 72 °C. The PCR products were resolvedon 1.5% agarose gels containing ethidium bromide. The DNA bandswith the expected sizes were extracted from the gel using gelextraction kits (Qiagen), according to the manufacturer’sinstructions.

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Table 1 Oligonucleotide primers used for PCR amplification of bovine LETF cDNAs and DNA

A standard PCR was used to amplify the promoter region of thebovine HNF-3 ${gamma}$ gene, with forward and reverse primers (Table 1

)that were designed based on the homologous DNA sequences betweenthe 5'-flanking regions of the human and mouse HNF-3 ${gamma}$ genes.The conditions of this PCR were 35 cycles of 30 s at 94 °C,1 min at 60 °C, and 2 min at 72 °C. The PCR productswere analyzed on agarose gels as described above.

Cloning and subcloning

The gel-extracted LETF cDNAs were ligated into pGEM-T Easy vector(Promega), essentially according to the manufacturer’sinstructions. The gel-extracted bovine HNF-3 ${gamma}$ promoter DNA wasinserted into pGL2B vector (Promega) at the NheI and HindIIIsites. The ligation was transformed into competent DH10B Escherichiacoli (Invitrogen) by electroporation and the positive cloneswere selected on the LB/Ampicillin/5-bromo-4-choloro-3-indolyl-ß-D-galactoside (X-Gal)/isopropyl thiogalactoside (IPTG) plates.The plasmid DNA from the selected E. coli cells was extractedusing the Qiagen miniprep kit (Qiagen) according to the manufacturer’sinstructions and analyzed for inclusion of inserts by digestionwith restriction enzyme EcoRI. In addition, the HNF-1 ${alpha}$ and HNF-3 ${gamma}$ cDNA inserts in their respective pGEM-T Easy plasmids were releasedwith restriction enzymes SpeI and EcoRI and were subcloned intopGEM-4Z vector (Promega) between cloning sites EcoRI and XbaI.

Sequencing and sequence analysis

The sequencing reaction was set up with 400 ng of the plasmidand 5 pmol vector specific primers in a volume of 10 µlusing the ABI Prism Big Dye Terminator cycle sequencing chemistry(Applied Biosystems, Foster City, CA, USA), run at 96 °Cfor 1 min, followed by 49 cycles of 96 °C for 10 s, 50 °Cfor 10 s, and 60 °C for 4 min. The sequencing reactionswere analyzed on ABI 377 Automated DNA Sequencers (Applied Biosystems).The nucleotide sequences of the cloned bovine LETF cDNAs andHNF-3 ${gamma}$ promoter DNA were compared with the sequences in GenBankusing the BLAST program at http://www.ncbi.nlm.nih.gov. Multiplesequence alignment was performed with the ClustalW program athttp://www.ebi.ac.uk.

In vitro transcription

The bovine LETF cDNA-containing plasmids cloned in this studyas well as the bovine HNF-4 ${alpha}$ cDNA (311 bp) plasmid cloned in aprevious study (Jiang & Lucy 2001) were linearized withappropriate restriction enzymes (Table 2). About 0.5 µgof each linearized plasmid was transcribed in vitro with eitherT7 or SP6 RNA polymerase (Table 2) in the presence of [ ${alpha}$ -³²P]CTPto generate antisense riboprobe for each LETF mRNA. The in vitrotranscription was carried out using the Riboprobe CombinationSystem kit (Promega), essentially according to the manufacturer’sinstructions. After transcription, free [ ${alpha}$ -³²P]CTP was removedfrom the probe by phenol–chloroform extraction and filtrationthrough quick spin Sephadex G-50 columns (Roche Molecular Biochemicals,Indianapolis, IN, USA). The specific activity of the purifiedprobe was estimated by liquid scintillation counting.

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Table 2 Cloning information of the bovine LETF cDNA plasmids

Ribonuclease protection assay (RPA)

The RPA was carried out using the RPA II kit (Ambion, Austin,TX, USA) according to the manufacturer’s instructions.Briefly, 20 µg total liver RNA, 1x10⁵ c.p.m. of one ortwo LETF riboprobes (C/EBP ${alpha}$ and C/EBPß mRNAs were analyzedin the same RPA, as were DBP and HNF-3ßmRNAs), and1x10⁵ c.p.m. glyceraldehyde-3-phosphate dehydrogenase (GAPDH)probe, which was synthesized as described before (Wang et al. 2003),were mixed in 20 µl hybridization buffer. The mixturewas incubated at 42 °C for about 16 h and then digestedwith 200 µl 1:100 diluted ribonucleases A and T₁ at 37°C for 45 min. The undigested RNA fragments were precipitatedand resolved on 6% polyacrylamide gels containing 7 M urea.The gels were dried, exposed to phosphor-screens, and scannedon a Molecular Imager FX System (BioRad, Hercules, CA, USA).The intensity of each protected band was measured using theAlpha Imager program (Alpha Innotech Corporation, San Leandro,CA, USA) and was used to represent the abundance of the correspondingmRNA. The intensity of the LETF mRNA band was adjusted to thatof the GAPDH mRNA in the same sample to normalize variationsin the starting amounts of RNA and variations in performingRPA.

Besides LETF mRNAs, IGF-I mRNA was also quantified in the liversamples, serving as a positive control for GH regulation ofgene expression in the liver of cows. This RPA was performedessentially as described before (Wang et al. 2003).

Statistical analysis

The LETF mRNA levels of different groups of cows were comparedusing General Linear Model ANOVA and Tukey’s proceduresof SAS (SAS Institute, Cary, NC, USA). Differences were consideredsignificant if P< 0.05. All data were expressed as means±S.E.M. (standard error of the mean).

Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Sequences of bovine LETF cDNAs

cDNA fragments between 150 base pair (bp) and 350 bp for bovineHNF-1 ${alpha}$ , HNF-1ß, HNF-3 ${alpha}$ , HNF-3ß, HNF-3 ${gamma}$ , HNF-6,DBP, C/EBP ${alpha}$ , and C/EBPß were cloned and sequenced (Table2). The sequences have been deposited in GenBank (Table 2).The sequences of the cloned bovine LETF cDNA fragments, exceptHNF-3 ${gamma}$ , share more than 90% and 84% identities with the correspondinghuman and mouse LETF sequences respectively. The bovine HNF-3 ${gamma}$ sequence is 85% and 78% identical to the human and mouse HNF-3 ${gamma}$ sequences respectively.

All 10 LETFs except HNF-1ßmRNA were detectable by RPA in the cow liver

The RPAs of 20 µg total RNA detected significant expressionof all ten LETFs except HNF-1ß in the liver of bothGH-treated and untreated cows (Figs 1A and 2A). (The RPA imagefor HNF-1ß is not shown.) However, HNF-1ßmRNA was detectable in fetal bovine liver (data not shown).The HNF-1ß mRNA is probably expressed at very lowlevels in the adult cow liver and GH probably does not stronglystimulate HNF-1ß expression in the cow liver, if ithas any stimulatory effect.

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Figure 1 RPAs of HNF-3 ${gamma}$ , HNF-4 ${alpha}$ , HNF-6, C/EBP ${alpha}$ , HNF-3ß, and DBP mRNAs in the livers of cows 6 h, 24 h, and 1 week after GH administration as well as untreated cows (control). (A) Phosphor images of the RPAs. In the RPA of each LETF mRNA, a probe specific for GAPDH mRNA was also included as a control for variations in starting amounts of RNA and the variations in performing RPA. Yeast tRNA (tRNA) was included in the RPA as a negative control. The ribonuclease-protected fragments corresponding to specific LETF and GAPDH mRNAs are indicated with arrows. The RPA of HNF-6 mRNA generated two protected bands that corresponded to splice variants HNF-6 ${alpha}$ and HNF-6ß(see text for details). The asterisk indicates a potentially unidentified DBP mRNA splice variant. The RPA for IGF-I mRNA served as a positive control for GH regulation of gene expression in the liver. (B) Relative abundance of HNF-3 ${gamma}$ , HNF-4 ${alpha}$ , HNF-6 ${alpha}$ , HNF-6ß, C/EBP ${alpha}$ , HNF-3ß, and DBP mRNAs as well as IGF-I mRNA. The relative abundance of each LETF mRNA or IGF-I mRNA was obtained by densitometric analysis of the RPA images in A. The density of each protected LETF or IGF-I mRNA band in each sample was normalized against that of protected GAPDH mRNA measured in the same RPA. All values are expressed as means ±S.E.M. (pooled). For each mRNA species, the means with different letters are significantly different (P< 0.05).

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Figure 2 RPAs of HNF-1 ${alpha}$ , HNF-3 ${alpha}$ , and C/EBPßmRNAs in the livers of cows 6 h, 24 h, and 1 week after GH administration as well as untreated cows (control). (A) Phosphor images of the RPAs. (B) Relative abundance of HNF-1 ${alpha}$ , HNF-3 ${alpha}$ , and C/EBPß mRNAs of different groups of cows. All values are expressed as means ± S.E.M. (pooled). There are no significant differences between the means (P> 0.05).

GH strongly stimulated HNF-3 ${gamma}$ expression

As revealed by RPAs (Fig. 1A), the liver expression of HNF-3 ${gamma}$ mRNAin the cows 24 h and 1 week after GH administration was higher(P< 0.05) than in the untreated cows or in the cows 6 h afterGH administration (Fig. 1B). The liver levels of HNF-3 ${gamma}$ mRNA were,however, not different between the untreated cows and the cows6 h after GH administration, or between the cows 24 h afterGH administration and the cows 1 week after GH administration(Fig. 1A,B). GH administration increased the HNF-3 ${gamma}$ mRNA expressionby more than fourfold (Fig. 1B). This magnitude of increasewas the greatest among the GH-induced increases in all LETFmRNAs (Fig. 1B) and was comparable to that of the GH-inducedincrease in the expression of IGF-I mRNA (Fig. 1A,B), a widelyknown target of GH action in the liver.

GH stimulated HNF-6, HNF-4 ${alpha}$ , and C/EB- ${alpha}$ expression weakly with different kinetics

The levels of HNF-4 ${alpha}$ mRNA in the liver of the cows 1 week afterGH administration were higher (P< 0.05) than in the untreatedcows (Fig. 1A,B). The levels of HNF-4 ${alpha}$ mRNA were not differentbetween the cows 6 h or 24 h after GH administration and theuntreated cows (Fig. 1A,B). Thus, GH administration increasedthe expression of HNF-4 ${alpha}$ mRNA in the liver of cows, but thiseffect appeared to take a longer time than did the effect ofGH on HNF-3 ${gamma}$ or IGF-I expression (Fig. 1A).

The RPA with a probe transcribed from the cloned HNF-6 cDNAgenerated two ribonuclease-protected mRNA fragments across theliver RNA samples (Fig. 1A). The longer band was apparentlyat the size (273 bp) of the cloned HNF-6 cDNA and the shorterprotected fragment was approximately 225 bp. These two protectedbands corresponded to the HNF-6 mRNA splice variants, HNF-6 ${alpha}$ mRNA and HNF-6beta; mRNA, which contains an insertion 43 bpdownstream from the 5' end of the cloned HNF-6 ${alpha}$ cDNA, based onthe sequences of the mouse HNF-6 ${alpha}$ and HNF-6ß mRNAs(Lemaigre et al. 1996). As in the mouse liver (Lemaigre et al. 1996),the HNF-6 ${alpha}$ mRNA was expressed at a higher level than theHNF-6ß mRNA in the bovine liver (Fig. 1A). The levelsof both HNF-6 ${alpha}$ and HNF-6ß mRNAs in the liver of thecows 24 h and 1 week after GH administration were higher (P<0.05) than in the untreated cows or the cows 6 h after GH administration(Fig. 1B). However, the levels of HNF-6 ${alpha}$ and HNF-6ßmRNAs were not different between the cows 6 h after GH administrationand the untreated cows, or between the cows 24 h after GH administrationand the cows 1 week after GH administration (Fig. 1B).

GH administration also increased C/EBP ${alpha}$ mRNA expression in theliver, as the levels of C/EBP ${alpha}$ mRNA were higher (P< 0.05)in the cows 24 h after GH administration than in the untreatedcows (Fig. 1A,B). In contrast to the stimulation of GH on HNF-3 ${gamma}$ , HNF-6, and IGF-I mRNA expression, GH stimulation of C/EBP ${alpha}$ expression appeared to be temporary, as the levels of C/EBP ${alpha}$ mRNA were not different between the cows 1 week after GH administrationand the untreated cows (Fig. 1A,B).

GH had initially a stimulatory effect and subsequently an inhibitory effect on liver expression of HNF-3ß and DBP mRNAs

Growth hormone appeared to have a transient stimulatory buta sustained inhibitory effect on the expression of HNF-3ßmRNA in the bovine liver, as the levels of HNF-3ßmRNA were higher (P< 0.05) in the cows 6 h after GH administrationbut lower (P=0.05) in the cows 24 h and 1 week after GH administrationcompared with those in the untreated cows (Fig. 1A,B).

The RPA with a probe transcribed from the cloned DBP cDNA generatedtwo ribonuclease-protected mRNA fragments across the liver RNAsamples (Fig. 1A). The longer band, in the size (184 bp) ofthe cloned DBP cDNA insert, corresponded to the cloned bovineDBP mRNA sequence. The shorter band, in the same expressionpattern as the longer band across the samples (Fig. 1A), probablyrepresented an unidentified splice variant of DBP mRNA. Comparedwith the untreated cows, the cows 6 h after GH administrationhad increased expression (P< 0.05) of DBP mRNA (both thelong and the short bands), the cows 24 h after GH administrationhad decreased expression (P< 0.05), and the cows 1 week afterGH administration had similar levels of DBP mRNA in the liver(Fig. 1A,B). Thus, like its effect on HNF-3ß, GH initiallyhad a stimulatory effect and then an inhibitory effect on DBPmRNA expression in the liver of cows.

GH had no effect on HNF-1 ${alpha}$ , C/EBPß and HNF-3 ${alpha}$ mRNA expression

The liver mRNA levels of other LETFs, including HNF-1 ${alpha}$ , HNF-3 ${alpha}$ ,and C/EBPß, were not different between the cows 6h, 24 h, and 1 week after GH administration and the untreatedcows (Fig. 2A,B), indicating that GH had no significant effecton the expression of these three LETF mRNAs in the cow liver.

The promoter of HNF-3 ${gamma}$ contains multiple potential STAT5-binding sites

Among the LETFs, the response of HNF-3 ${gamma}$ to GH appeared to bethe strongest and was similar in magnitude and time-course tothe IGF-I response to GH (Fig. 1). The GH regulation of theexpression of IGF-I (Woelfle et al. 2003) and several othergenes (Bergad et al. 1995, Davey et al. 1999, Woelfle & Rotwein 2004)in the liver has been shown to be mediated bySTAT5. To determine if GH stimulation of HNF-3 ${gamma}$ expression isalso mediated by STAT5, a 967 bp promoter region of the bovineHNF-3 ${gamma}$ gene was cloned and sequenced (Fig. 3A). A search of thispromoter region for transcription factor binding sites revealedthree potential STAT5 binding sites (Fig. 3A) that are nearlyidentical to the consensus STAT5 binding sequence TTCN₃GAA (whereN is any nucleotide) (Ehret et al. 2001). Aligning the correspondingDNA regions of the bovine, human, and mouse HNF-3 ${gamma}$ genes furtherrevealed that two of the putative STAT5 binding sites are highlyconserved among these three species (Fig. 3B). The two STAT5binding sites are also conserved in the corresponding rat genomicregion (data not shown).

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Figure 3 The promoter of HNF-3 ${gamma}$ contains putative STAT5-binding sites. (A) Sequence of a 967 bp promoter region of the bovine HNF-3 ${gamma}$ gene. Underlined are three putative STAT5-binding sites; in bold is the translation start codon (ATG) for HNF-3 ${gamma}$ protein. (B) Alignment of corresponding regions of the human (h), mouse (m) and bovine (b) HNF-3 ${gamma}$ promoters. Shaded are two conserved STAT5 binding sites. The bovine sequence corresponds to the region between 111 and 210 in panel A of this figure. The human and mouse sequences correspond to the region between 92919 and 93018 in GenBank accession number AC008623 [GenBank] .4 and the region between 185588 and 185689 in GenBank accession number AC145199 [GenBank] .3 respectively.

	Discussion

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The expression of many genes in the liver has been shown tobe regulated by GH (Thompson et al. 2000, Flores-Morales etal. 2001, Olsson et al. 2003, Ahluwalia et al. 2004). As partof the effort to understand the mechanism by which GH regulatesgene expression in the liver, we have analyzed the effect ofadministration of slow-release GH (equivalent to continuousGH administration) on the expression of 10 LETF genes in theliver of cows. Our data indicate that continuous GH administrationhas a sustained stimulatory effect on the expression of HNF-6,HNF-4 ${alpha}$ , and C/EBP ${alpha}$ , and initially has a stimulatory and subsequentlyan inhibitory effect on the expression of HNF-3ß inthe bovine liver. These findings in general agree with the observationsfrom studying the effect of GH on the expression of HNF-6 (Lahuna et al. 1997),HNF-4 ${alpha}$ and HNF-3ß (Lahuna et al. 2000)and C/EBP ${alpha}$ (Rastegar et al. 2000. Strand et al. 2000) in theliver of hypophysectomized rats or cultured primary hepatocytes.The only major difference is that the GH-induced changes inthese LETF mRNAs in cows were much smaller (less than onefold)than those observed in hypophysectomized rats (several folds).The reason for this difference is probably because hypophysectomizedrats are much more sensitive to GH action than pituitary-intactcows.

The data from the present study also indicate that during theone-week course of GH treatment, the expression of HNF-1 ${alpha}$ mRNAin the bovine liver was not changed. In earlier studies by others(Le Stunff et al. 1996, Rastegar et al. 2000), the liver levelsof HNF-1 ${alpha}$ protein in rats were not altered by hypophysectomyor GH replacement. These observations together suggest thatGH does not regulate the expression of HNF-1 ${alpha}$ in the liver. Theeffect of GH on other LETFs, including C/EBPß, DBP,and HNF-3 ${gamma}$ , has not been reported or suggested by the literature.Our data from this study show that GH administration for oneweek had no effect on the expression of C/EBPß mRNAbut had a strong, sustained stimulatory effect on the expressionof HNF-3 ${gamma}$ mRNA and a biphasic effect, like that on HNF-3ß,on the expression of DBP mRNA in the bovine liver. Thus, HNF-3 ${gamma}$ and DBP are two new LETFs the expression of which is regulatedby GH in the liver.

The mechanism by which GH regulates the expression of HNF-3 ${gamma}$ ,HNF-3ß, HNF-6, HNF-4 ${alpha}$ , C/EBP ${alpha}$ , and DBP mRNAs in thebovine liver was not a focus of this study. However, cloningand sequencing the promoter region of the HNF-3 ${gamma}$ gene, the LETFthat was most sensitive to GH regulation, revealed two putativebinding sites for STAT5, the same transcription factor thathas been shown to be directly involved in GH regulation of theexpression of Spi 2.1 (Bergad et al. 1995), IGF-I (Woelfle etal. 2003), ALS (Ooi et al. 1997), and HNF-6 (Lahuna et al. 2000).A sequence alignment further indicated that the sequences ofthe putative STAT5 binding sites are also conserved in the promoterregions of the human, mouse, and rat HNF-3 ${gamma}$ genes. Functionallyimportant cis-regulatory regions are often conserved duringevolution (Cooper & Sidow 2003, Thomas et al. 2003). Containingmultiple and evolutionally conserved sequences of STAT5 bindingsites suggests that GH may regulate HNF-3 ${gamma}$ mRNA expression inthe liver through direct binding of STAT5 to the HNF-3 ${gamma}$ promoter.This potential mechanism, as well as the mechanisms underlyingGH regulation of other LETFs, warrants further studies.

Given the role of LETFs as major transcription factors controllingthe expression of many genes in the liver (Cereghini 1996, Hayashi et al. 1999,Schrem et al. 2002), being regulated by GH suggeststhat they may be part of the transcription factor network mediatingGH regulation of other genes in the liver. A cross examinationof the list of genes that have been shown to be regulated byGH (Thompson et al. 2000, Flores-Morales et al. 2001, Olsson et al. 2003,Ahluwalia et al. 2004) and the list of genes thathave been identified to contain binding sites for HNF-3 ${gamma}$ , HNF-3ß,HNF-6, HNF-4 ${alpha}$ , C/EBP ${alpha}$ , or DBP (Schrem et al. 2002, Odom et al. 2004)could identify a number of candidate genes whose expressionin the liver may be regulated by GH through these LETFs. Forexample, the expression of CYP3A4 (Liddle et al. 1998, Jaffe et al. 2002),tyrosine-aminotransferase (TAT) (Ahluwalia etal. 2004), and transferrin (Tf) (Flores-Morales et al. 2001)in the liver were shown to be stimulated by continuous GH administration.The expression of CYP3A4 (Rodriguez-Antona et al. 2003), andTAT and Tf (Kaestner et al. 1998) in the liver has also beenshown to depend on HNF-3 ${gamma}$ . Now that HNF-3 ${gamma}$ expression is foundto be stimulated by GH in the liver, it is reasonable to suspectthat GH may stimulate CYP3A4, TAT, and Tf expression in theliver through increased HNF-3 ${gamma}$ expression.

Being regulated by GH also suggests that the genes containingbinding sites for HNF-3 ${gamma}$ , HNF-3ß, HNF-6, HNF-4 ${alpha}$ , C/EBP ${alpha}$ ,and DBP might also be target genes of GH regulation in the liver.The promoters of many genes have been found to contain bindingsites for LETFs (Schrem et al. 2002). A recent study employingpromoter microarrays identified that 12%, 1.7%, and 1.6% of13 000 gene promoters were bound by HNF-4 ${alpha}$ , HNF-1 ${alpha}$ , and HNF-6in hepatocytes respectively (Odom et al. 2004). Thus, the numberof genes whose expression in the liver is regulated by GH mightbe much larger than has been indicated by gene expression studiesusing cDNA or oligonucleotide microarrays (Thompson et al. 2000,Flores-Morales et al. 2001, Olsson et al. 2003, Ahluwalia etal. 2004).

Compared with HNF-3 ${gamma}$ , HNF-3ß, HNF-4 ${alpha}$ , HNF-6, C/EBP ${alpha}$ ,and DBP, the mRNA expression of HNF-1 ${alpha}$ , HNF-3 ${alpha}$ , and C/EBPßin the bovine liver was not affected by GH. This, however, doesnot necessarily suggest that HNF-1 ${alpha}$ , HNF-3 ${alpha}$ , and C/EBPßcannot contribute to GH regulation of gene expression. The abilityof a transcription factor to affect gene transcription can becontrolled at both concentration and activity, each at multiplelevels (Calkhoven & Ab 1996). It is possible that GH regulatesthese LETFs (as well as other LETFs) at the translational level,thereby changing their protein concentrations; it is also possiblethat GH regulates these LETFs (as well as other LETFs) at theposttranslational level and hence the DNA binding activity orthe ability of them to interact with other regulatory proteins.These possibilities remain to be tested in future studies.

In summary, the results of this study indicate that GH can regulatethe mRNA expression of HNF-3 ${gamma}$ and five other LETFs includingHNF-3ß, HNF-6, HNF-4 ${alpha}$ , C/EBP ${alpha}$ , and DBP in the bovineliver. These LETFs, therefore, have great potential to mediateGH regulation of other genes in the liver. The study also suggeststhat GH regulation of HNF-3 ${gamma}$ expression in the bovine liver maybe mediated by direct binding of STAT5 to the HNF-3 ${gamma}$ promoter.

Acknowledgements

We are grateful to William Beal and his group for daily animalcare and William Swecker Jr for assistance with liver biopsysampling.

Funding

The authors declare that there is no conflict of interest thatwould prejudice the impartiality of this scientific work.

References

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

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Received 23 September 2004
Accepted 15 October 2004

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				J. H Lo, P. P. Chiou, C M Lin, and T. T Chen Molecular cloning and expression analysis of rainbow trout (Oncorhynchus mykiss) CCAAT/enhancer binding protein genes and their responses to induction by GH in vitro and in vivo J. Endocrinol., August 1, 2007; 194(2): 393 - 406. [Abstract] [Full Text] [PDF]

				H. Jiang, Y. Wang, M. Wu, Z. Gu, S. J. Frank, and R. Torres-Diaz Growth Hormone Stimulates Hepatic Expression of Bovine Growth Hormone Receptor Messenger Ribonucleic Acid through Signal Transducer and Activator of Transcription 5 Activation of a Major Growth Hormone Receptor Gene Promoter Endocrinology, July 1, 2007; 148(7): 3307 - 3315. [Abstract] [Full Text] [PDF]