Báo cáo Y học: Ontogeny and subcellular localization of rat liver mitochondrial branched chain amino-acid aminotransferase docx

Tovar1 1 Departamento de Fisiologı´a de la Nutricio´n, Instituto Nacional de Ciencias Me´dicas y Nutricio´n ‘Salvador Zubira´n’, Me´xico; 2 Departamento de Patologı´a Experimental, Insti

Ontogeny and subcellular localization of rat liver mitochondrial

branched chain amino-acid aminotransferase

Nimbe Torres1, Carolina Vargas1, Rogelio Herna´ndez-Pando2, He´ctor Orozco2, Susan M Hutson3and Armando R Tovar1

1 Departamento de Fisiologı´a de la Nutricio´n, Instituto Nacional de Ciencias Me´dicas y Nutricio´n ‘Salvador Zubira´n’, Me´xico;

2 Departamento de Patologı´a Experimental, Instituto Nacional de Ciencias Me´dicas y Nutricio´n ‘Salvador Zubira´n’,Me´xico;3Department of Biochemistry, Wake Forest University Medical Center, Winston-Salem, North Carolina, USA

Branched chain amino-acid aminotransferase (BCAT)

activity is present in fetal liver but the developmental

pattern of mitochondrial BCAT (BCATm) expression in rat

liver has not been studied The aim of this study was to

determine the activity, protein and mRNA concentration of

BCATm in fetal and postnatal rat liver, and to localize this

enzyme at the cellular and subcellular levels at both

developmental stages Maximal BCAT activity and BCATm

mRNA expression occurred at 17 days’ gestation in fetal rat

liver and then declined significantly immediately after birth

This pattern was observed only in liver; rat heart showed a

different developmental pattern Fetal liver showed intense

immunostaining to BCATm in the nuclei and mitochondria

of hepatic cells and blood cell precursors; in contrast, adult

liver showed mild immunoreactivity located only in the

mitochondria of hepatocytes BCAT activity in isolated fetal liver nuclei was 0.64 mU:mg21 protein whereas it was undetectable in adult liver nuclei By Western blot analysis the BCATm antibody recognized a 41-kDa protein in fetal liver nuclei, and proteins of 41 and 43 kDa in fetal liver supernatant In adult rat liver supernatant, the BCATm antibody recognized only a 43-kDa protein; however, neither protein was detected in adult rat liver nuclei The appearance of the 41-kDa protein was associated with the presence of the highly active form of BCATm These results suggest the existence of active and inactive forms of BCAT

in rat liver

Keywords: branched-chain amino acids; mitochondria; nuclei; ontogeny

The branched-chain amino acids (BCAA) leucine,

iso-leucine, and valine are required mainly for body protein

synthesis The initial enzymes for catabolism of the BCAA

are regulated differently from other amino-acid degrading

enzymes The first step in the degradation of these amino

acids is a reversible transamination catalyzed by the

branched chain amino-acid aminotransferase (BCAT;

EC 2.6.1.42) The products of this reaction are the

corresponding branched chain 2-oxo acids that can be

reaminated to their corresponding amino acids [1], or

irreversibly decarboxylated by the branched-chain 2-oxo

acid dehydrogenase complex (BCODC) forming the

corresponding acyl CoA derivates In mammals there are

two BCAT isoenzymes, a mitochondrial (BCATm), and a

cytosolic (BCATc) form [2,3] In the rat BCATm is the

predominant isoenzyme, and it is found in almost all tissues

with the highest activity in pancreas and stomach, intermediate activity in heart and kidney, low activity in skeletal muscle and skin and negligible activity in adult liver BCAT activity is accompanied by a similar pattern of BCATm mRNA expression [4] The cytosolic form is restricted to brain, ovary and placenta [5] BCATm cDNA encodes a polypeptide of 366 amino acids preceded by a pre-sequence of 27 amino acids with a molecular mass of the mature protein of 41.2 kDa The mature rat sequence is 82% and 95% identical to the human and murine BCATm respectively [6] and 82% identical to sheep BCATm [7] In contrast with other hepatic amino-acid degrading enzymes [4], BCATm expression is not regulated by glucagon, glucocorticoids or high dietary protein However, BCATm mRNA expression is highly induced in lactating mammary tissue and declines rapidly after weaning [8,9]

Previous studies have shown that fetal rat liver, in contrast with adult rat liver, has BCAT activity but that this declines rapidly after birth [10,11] This decrease was associated mainly with a decrease in the volume fraction of hematopoietic cells in fetal rat liver [11] assuming that the enzyme activity was confined to only hematopoietic cells and not to hepatic cells However, studies with freshly isolated hepatocytes from 18-days gestation fetal rats and fetal hepatocytes cultured for 2 days showed BCAT activity, indicating the possibility that not only the hematopoietic cells were responsible for BCAT activity but that fetal hepatocytes may contribute also to the enzyme activity [12]

In the present study, we measured the BCAT activity, amount of protein and BCATm mRNA expression pattern as well as the immunolocalization at cellular and subcellular

Correspondence to A R Tovar Departamento de Fisiologı´a de la

Nutricio´n, Instituto Nacional de Ciencias Me´dicas Nutricio´n ‘Salvador

Zubira´n’, Me´xico DF 14300, Me´xico Fax: 1 525 6551076,

Tel.: 1 525 5731200 ext 2801/2802,

E-mail: artovar@quetzal.innsz.mx

Enzymes: branched chain amino acid aminotransferase (BCAT, EC

2.6.1.42).

(Received 25 June 2001, revised 27 September 2001, accepted

28 September 2001)

Abbreviations: BCAT, branched chain amino-acid aminotransferase;

BCATm, mitochondrial BCAT; BCAA, branched chain amino acids;

BCATc, cytosolic BCAT; BCODC, branched chain 2-oxo acid

dehydrogenase complex.

level of fetal and adult liver rats The results show a new

localization of BCATm in the nuclei of fetal hepatocytes and

the presence of an active and inactive form of the BCATm in

fetal and adult liver, respectively

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

Fetal livers

Wistar rats of 17- and 19-days gestation were used

Gestational age was determined by vaginal smear to detect

spermatozoa Fetal livers were removed immediately,

pooled and then divided in to aliquots for RNA extraction,

Western blot analysis, BCAT enzyme assay and

immuno-histochemical studies Heart and kidney were also processed

for comparison purposes Samples for RNA extraction were

frozen in liquid nitrogen This study was approved by the

Committee of Animal Research of the Instituto Nacional de

Ciencias Me´dicas y Nutricio´n ‘Salvador Zubira´n’, Me´xico

Preparation of the supernatant fraction for BCAT assay

A sample of liver, kidney or heart was suspended in buffer

(4 mL extraction buffer per gram tissue) containing 225 mM

mannitol, 75 mMsucrose, 0.1 mMEDTA, 5 mMMops and a

mix of protease inhibitors including 1 mM EDTA, 1 mM

EGTA, 1 mM diisopropylfluorophosphate, 5 mM

benzami-dine, 5 mM dithiothreitol, 10 mg:mL21 leupeptin and 1%

Triton X-100 Supernatant fraction of fetal liver or heart was

obtained from a pool of 19 – 24 fetuses The tissue

suspension was centrifuged at 30 000 g for 60 min at

4 8C The supernatant was assayed for BCAT activity

Isolation of nuclei

Nuclei were isolated as described [13] Liver was

homogenated in 10 mM Tris/HCl pH 7.5 containing 0.3M

sucrose, 5 mM dithiothreitol and 0.05% triton X-100 After

centrifugation at 83 000 g for 45 min with an 70 Ti rotor at

4 8C through a cushion of 2.3M sucrose, 2 mM MgCl2,

10 mMTris/HCl pH 7.5, nuclei were counted and suspended

at a concentration of 2  107 in buffer containing 50%

glycerol, 2 mM MgCl2 0.1 mM EDTA, 50 mM Hepes

pH 7.5, 0.1 mM phenylmethanesulfonyl fluoride, and were

stored at 280 8C until use Electron-microscopic analysis

revealed no contamination with mitochondria or other

cytoplasmic materials

Determination of branched-chain amino-acid

aminotransferase activity

BCAT activity was assayed in all the supernatants and nuclei

by the method described previously [4,14] Activity was

measured at 37 8C in 50 mM potassium phosphate buffer

pH 7.8, which contained 50 mM pyridoxal phosphate and

4 g:L21Chaps Fifty microliters of supernatant were added

to the assay, and the reaction was initiated by addition of a

mixture containing 1.0 mM2-oxo[1-14C]isocaproate/12 mM

isoleucine The specific activity for 2-oxo[1-14C]isocaproate

was 3.3 Bq:nmol21 After 5 min the reaction was stopped

by addition of 500 mL of 2Msodium acetate pH 3.4 The

remaining 2-oxo[1-14C]isocaproate not transaminated was

chemically decarboxylated by adding 250 mL of 30%

hydrogen peroxide A sample of 250 mL of the reaction mixture was added to a scintillation vial Then 10 mL of liquid scintillation cocktail (BCS, Amersham) was added and samples were counted (Wallac, Turku, Finland) Each assay was performed in duplicate A unit of activity was defined as 1 mmol [1-14C]leucine formed per min at 37 8C BCAT specific activity was expressed as mU:mg protein21

SDS/PAGE SDS/PAGE was carried out according to Ausubel et al [13]

in 10% gels using 40 mg of protein Prior to electrophoresis, all samples were boiled for 5 min in the presence of 4% SDS, with 2% 2-mercaptoethanol Premixed protein molecular weight markers (low range) were used for molecular mass determination (Boehringer Mannheim)

Immunoblotting After electrophoresis the separated proteins were transferred

to poly(viynlidene difluoride) Western blotting membranes (Boehringer Mannheim) The transfer was carried out in a Transphor electrophoresis unit (Hoefer Scientific Instru-ments) following the manufacturer’s instructions The poly(viynlidene difluoride) membranes were treated with 1.5% gelatin/1.5% albumin for 2 h at 37 8C and incubated with anti-(rat BCATm) IgG (1 : 2500) for 1.5 h at room temperature Immunoreactive protein bands were visualized using horseradish peroxidase-labeled goat anti-(rabbit Ig) Ig (1 : 6000) after the oxidation of luminol as luminescent substrate The light emission was detected by a short exposure to autoradiography film (ECL, Amersham Life Science) Anti-(rat BCATm) IgG was obtained as described previously [2] Immunoblot analysis using mitochondrial or tissue extracts from several tissues have shown only a single band with a Mrof 41 kDa, indicating that the antibody does not cross react with other proteins and that it recognizes BCATm epitopes [9,12]

Isolation of total RNA and Northern blot analysis Total RNA was isolated from liver, heart, or placenta according to Chomczynski and Sacchi [15] For Northern analysis, 20 mg RNA was subjected to electrophoresis in a 1.5% agarose gel containing 37% formaldehyde and transferred to a nylon membrane filter Hybond-N1 (Amersham) and cross-linked with a UV crosslinker (Amersham) The probe was a 900-bp Pst1 – Eco R1 fragment of rat BCATm cDNA cloned in pT7 Bluescript [6] and labeled with deoxycytidine 50[a-32P]dCTP (3000 Ci:mmol21, Amersham) using the rediprime DNA labeling system (Amersham) Filters were prehybridized with rapid-hyb buffer (Amersham) at 65 8C for 45 min, and then hybridized with the labeled probe for 2.5 h at 65 8C Membranes were washed once with 2  NaCl/Cit, 0.1% SDS at room temperature for 20 min and then washed twice with 0.1  NaCl/Cit, 0.1% SDS at 65 8C for 15 min each Digitized images were prepared and quantitation of radioactivity in the bands was carried out by using the Instant Imager electronic autoradiography system (Packard Instruments) Membranes were also exposed to Extascan film (Kodak) at 270 8C with an intensifying screen

Reverse transcription (RT)/PCR was performed with 5 mg

RNA from rat fetal or adult liver, and kidney Total RNA

was treated with DNAse (Life Technologies) and the RT

was primed with oligo(dT) Specific oligonucleotides

for BCATm used for PCR amplification were: forward

primer, 50-ATCCAGCCCTTCCAGAACC-30 and reverse

primer, 50-AGCCGATCCAACCAGGTAG-30corresponding

to nucleotides 248 – 265 and 1208 – 1226 of rat heart

BCATm cDNA, respectively [6] The reaction produced a

979-bp product when kidney or heart mRNA were used

The oligonucleotides were synthesized with a

Beckman Oligo 1000 DNA synthesizer The product was

sequenced by using dideoxinucleotide terminators

(Amersham)

50 and 30RACE of liver BCATm cDNA

Total RNA from adult rat liver was isolated as described

above 50 and 30 RACE was carried out according to

manufacturer instructions (Life Technologies) Gene

specific primers, including nested primers, were designed

based on the RT/PCR product of BCATm amplified from

adult rat liver The external and nested gene specific reverse

primers for the 50 RACE amplification were: 50-GGCGTA

GAGTAGT-30 corresponding to nucleotides 339 – 359 and

297 – 317 of rat heart BCATm cDNA, respectively The

external and nested gene specific forward primers for the 30 RACE amplification were: 50-CAGAAGGAGTTGAAGG CTATT-30and 50-ACGGAACCAGTGCCCACGATT-30 cor-responding to nucleotides 1127 – 1147 and 1152 – 1172 of rat heart BCATm cDNA, respectively Products of 50 and

30 RACE were sequenced by using dideoxinucleotide terminators (Amersham)

Fig 1 Developmental pattern of hepatic BCAT activity, amount of

BCATm protein and BCATm mRNA levels in the rat (A) BCAT

activity in fetal and postnatal liver Data are expressed as mean ^ SEM;

n ¼ 3 – 19 (B) Western blot analysis of BCATm using anti-BCATm.

(C) Northern blot analysis of BCATm mRNA All lanes contained liver

total RNA from at least three rats.

Fig 2 Immunohistochemical localization of BCATm in fetal and adult liver (A) Fetal liver showed intense immuno-staining in the cytoplasm (arrows) and nuclei (white asterisks), as well as in nuclei of megacaryocytes located in the sinusoidal lumen (arrowheads) (B) In contrast, adult liver showed mild immunostaining confined to the cytoplasm of hepatocytes (both micrographs  400).

Histology, immunohistochemistry and immunoelectronic

microscopy

For light microscopy, fetal and adult liver slices were fixed

by immersion in absolute ethanol for 24 h, embedded in

paraffin, sectioned at 5 mm, and stained with hematoxylin

and eosin for histological analysis Imunohistochemical

detection of the BCATm was performed with the rabbit

anti-(rat BCATm) IgG fraction Before incubation with the

primary antibody, the endogenous peroxidase activity was

quenched with 0.03% H2O2 in absolute methanol; liver

sections were then incubated with the primary antibody

diluted 1 : 500 in NaCl/Pi overnight at 4 8C Bound

antibodies were detected with goat anti-(rabbit IgG) Ig

labeled with peroxidase diluted 1 : 100 in NaCl/Pi and

diaminobenzidine For negative controls tissue was

incubated with primary antibody previously pre-adsorbed

with purified enzyme

For immunoelectron microscopy studies, small tissue

fragments of fetal and adult liver were fixed by immersion in

4% paraformaldehyde dissolved in Sorensen’s buffer pH 7.4

for 2 h at 4 8C After rinsing, free aldehyde groups were

blocked in 0.5MNH4Cl in NaCl/Pifor 1 h Tissue samples

were dehydrated in graded ethyl alcohols and embedded in

LR-White hydrosoluble resin The same fixation and

embedding procedure was used for nuclei isolated from

liver by differential ultracentrifugation Thin sections

(between 70 and 90 nm) were placed on nickel grids; the

grids were then incubated with the rabbit anti-(rat BCATm)

IgG fraction diluted 1 : 100 in NaCl/Piwith 1% BSA and

0.5% Tween After rinsing repeatedly with NaCl/Pi, the

grids were incubated with goat anti-(rabbit IgG) Ig

conjugated to 5 nm gold particles diluted 1 : 20 in the

same buffer The grids were stained with uranium salts and

examined in a Zeiss EM 10 electron microscope For

quantification, electron micrographs at a magnification of

 40 000 were taken and the number of gold particles in 20

consecutive randomly chosen hepatocyte nuclei from fetal

and adult liver sections were counted

Chemicals and reagents

L-[1-14C]Leucine and the nucleotide [a-32P]dCTP were

from Dupont NEN The radioactive 2-oxo[1-14

C]isocapro-ate was synthesized from [1-14C]leucine as described

previously [16] All other reagents were obtained from

commercial sources and were at least reagent grade

R E S U L T S

Developmental pattern of liver BCAT activity

Maximal BCAT activity, 7.28 mU:mg protein21, occurred in

fetal liver at 17 days’ gestation BCAT activity decreased

significantly after birth: by 68% and 94% at birth and 21 days after birth, respectively Mean BCAT activity in adult rat liver was 0.38 ^ 0.05 mU:mg protein21, approximately 2% of that in heart After day 20 postnatal, liver BCAT specific activity remained low, similar to the levels reported

in the literature (Fig 1A)

Fig 3 Subcellular localization of BCATm in fetal and adult liver

by immunoelectron microscopy (A) Fetal hepatocytes showed

immunolabeling in mitochondria (m) and chromatin (c) associated to

the nuclear membrane (nm) ( 50 000) (B) The same pattern of

nuclear immunolabeling was seen in nuclei isolated from fetal liver by

differential ultracentrifugation at 32 000 g (C) At the structural level,

adult hepatocytes showed immunolabeling in mitochondria (m), and

occasional gold particles were found in cytoplasm ( 50 000).

Bar ¼ 0.5 mm.

Immunohistochemical localization of BCATm in fetal rat

liver

Fetal rat liver showed intense immunostaining to BCATm in

the cytoplasm and nuclei of hepatocytes, as well as in the

nuclei of blood cell precursors, particularly megakaryocytes

(Fig 2A) At the structural level, immunogold particles

were seen in the mitochondria and nuclei of fetal

hepatocytes, particularly intense immunoreactivity was

found in chromatin associated with the nuclear membrane

(Fig 3A) The nuclei of blood cell precursors showed

similar amounts and distribution of gold particles In

contrast, adult liver showed only mild immunoreactivity

located exclusively in the cytoplasm of hepatocytes

(Fig 2B) At the subcellular level, adult hepatocytes

showed immunolabeling in mitochondria and

immuno-reactivity in small vacuoles located near to the endoplasmic

reticulum No labeling at all was observed in the nuclei

(Fig 3C) The quantitative study revealed that fetal

hepatocyte nuclei had 309 ^ 34 gold particles, whereas

hepatocyte nuclei of adult liver had 13 ^ 6 gold particles

(P , 0.00007) The same immunolabeling pattern and similar

amount of gold particles was seen in isolated fetal liver

nuclei obtained by differential centrifugation (Fig 3B)

Mitochondria were absent from these preparations

Nuclear BCAT activity

This new localization of the BCATm in liver nuclei raised

the question of whether any of the enzyme activity was

actually associated with the nuclei of liver cells To answer

this question, BCAT activity was measured in liver

supernatant and isolated nuclei from fetal and adult rats

The specific activities of BCAT from 17-days’ gestation

fetal liver and adult liver are shown in Fig 4 Fetal liver

nuclear BCAT specific activity was 0.65 ^ 0.08 mU:mg

protein21whereas it was undetectable in adult liver nuclei

These results indicate that approximately 10% of the BCAT

activity in fetal liver is associated with the nuclei BCAT

specific activity in fetal liver was 19-fold higher than in the

adult liver supernatant, indicating that liver has a high

capacity for transamination of BCAA during the fetal stage,

but that this is lost after birth Furthermore, BCAT specific

activity in fetal liver is 35% of that found in adult heart

which is considered to be one of the organs with high BCAT

activity

Western blot analysis of BCATm in fetal and adult rat liver

When equal amounts of protein (40 mg) were subjected to

SDS/PAGE and immunoblotting, a 41-kDa protein

corre-sponding to the active form of BCATm was detected in fetal

liver nuclei, fetal liver supernatant, heart supernatant and

kidney mitochondria However, this protein was not found in

adult liver nuclei or adult liver supernatant, indicating that

the protein found in fetal liver nuclei was the same of that

found in kidney and heart The BCATm antiserum

recognized a protein of < 43 kDa in addition to the

41-kDa protein in fetal liver supernatant In adult liver

supernatant only a faint 43-kDa band was seen (Fig 4)

Thus, the appearance of the 41-kDa protein on immunoblots

was always associated with the presence of the highly active

form of BCATm These results suggest the existence of an

active and inactive form of the BCAT, and the develop-mental changes in BCAT activity in rat liver coincided with the appearance and disappearance of the 41-kDa BCATm (Fig 1B)

BCATm mRNA expression in fetal and adult rat liver The expression of BCATm during fetal development in the rat was examined by measuring BCATm mRNA abundance Northern blot analysis detected a band of 1.7 kb that corresponds to the size of the mRNA reported for this enzyme in rat heart [6] However, the expression of BCATm mRNA in liver was detectable by Northern blot analysis only on days 17 and 19 of gestation but not after birth (Fig 1C) As we detected a protein of 43 kDa in adult liver with BCATm antiserum by Western blotting, we considered that the apparent absence of BCATm mRNA in adult rat liver was perhaps associated with the low abundance of its message, and that the Northern blot analysis was not sensitive enough to detect it A RT/PCR assay was carried out using primers designed to amplify an internal sequence

of BCATm cDNA A band of 979 bp was detected when total RNA from adult liver, fetal liver or kidney were used, indicating that the RNA that codes for the 43 kDa is possibly derived from the BCATm gene (Fig 5) Sequenc-ing of the PCR product obtained from adult rat liver showed

Fig 4 Western blot analysis and enzyme activity of BCATm in different cell fractions Cell fractions were obtained as described in Materials and methods.

Fig 5 Expression of BCATm mRNA in kidney and adult or fetal liver Total RNA was isolated from kidney and liver cDNA was obtained by reverse transcription, and BCATm cDNA was amplified by PCR using primers specific for rat BCATm The size of the product obtained was 979 bp b-actin was used as standard for mRNA integrity.

100% homology with the sequence of BCATm heart cDNA.

Furthermore, 50and 30RACE amplified the end terminals of

rat liver cDNA, and a single band for each amplification was

obtained The sequence of the products of both

amplifica-tions also showed 100% homology with rat heart BCATm

cDNA These results suggest that the low abundance mRNA

for the 43-kDa protein is possibly derived from the same

gene that produces the 41-kDa protein

Developmental pattern of heart BCAT

BCAT activity in heart showed a different developmental

pattern than that observed in liver BCAT activity increased

significantly (P , 0.01) up to day 21 after birth, and it was

25% higher with respect to the activity at birth On day 21,

the BCAT activity reached the values reported for this organ

in adults rats Western blot and Northern blot analysis

followed a similar pattern (Fig 6A, and C)

D I S C U S S I O N

The activity of several hepatic amino-acid degrading

enzymes is absent or low during fetal life, increases rapidly

at birth, and reaches the activity level found in adults from

12 h to several days after birth [17 – 20] On the contrary, the

activity of hepatic BCAT followed a different

develop-mental pattern Fetal liver showed significant BCAT activity

and BCATm mRNA expression decayed immediately after

birth Postnatal liver showed low BCAT activity and negligible

BCATm mRNA expression This pattern is observed in only liver, as BCAT activity, amount of protein and BCATm mRNA expression was present in heart during the fetal stage and increased progressively as a function of age (Fig 6) Furthermore, this developmental pattern was specific for BCATm in liver as BCATc expression was not observed in this organ (data not shown) Previous studies indicated that BCAT activity in fetal liver was associated with hemato-poietic cells Our immunohistochemical results showed that BCATm is located in the nuclei and mitochondria of fetal hepatic and hematopoietic cells; however, the proportion of the former is greater than the latter indicating that the contribution of BCATm activity is associated mainly to hepatic cells

This is the first report showing that BCATm is localized

in two subcellular organelles, the mitochondria and the nucleus in fetal liver The majority of proteins have only one cellular destination; however, there is a class of enzymes called sorting isozymes that are produced by the same gene and that have multiple destinations [21] Some enzymes of this class are found in mitochondria and the cytoplasm [22,23], cytoplasm and nuclei [24], mitochondria, cyto-plasm and nuclei [21], and mitochondria and nuclei [25] It has been established that the 27 amino-acid pre-sequence of BCATm contains information to target this enzyme to the mitochondria [6] However, the nuclear import of proteins from the cytoplasm depends in part on the presence of a short stretch of cationic amino acids containing four to six residues of lysine or arginine [26] An examination of the mature BCATm protein showed that it does not contain a typical consensus sequence for its import to the nuclei However this protein contains two cationic rich stretches, located between amino acids 80 and 90 (KAYKGR DKQVR) and 290 and 299 (RKVTMKELKR) that may contribute to the nuclear localization of the enzyme Perhaps BCATm protein is transported to the nuclei by a specific importin [27] that is present only during fetal life

The high expression of BCATm during fetal life and the very low branched-chain 2-oxo acid dehydrogenase complex activity in liver and heart [20] reduce the oxidation

Fig 6 Developmental pattern of BCAT activity, amount of BCATm

protein and BCATm mRNA levels in rat heart (A) BCAT activity in

fetal and postnatal heart The results are expressed as mean ^ SEM,

n ¼ 4 – 24 (B) Western blot analysis of BCATm using anti-BCATm.

(C) Northern blot analysis of BCATm mRNA All lanes contained heart

total RNA from at least four different rats.

Fig 7 Northern blot analysis of BCATc and BCATm in rat placenta Total RNA was isolated from placenta of rats on day 17 and

19 of gestation as described in Materials and methods Blots were hybridized with the 900 bp Pst1 Eco R1 fragment of rat BCATm cDNA

or the 1400 bp Eco R1 fragment of rat BCATc cDNA [35].

of BCAA: there is no need life for the disposal of these

amino acids during fetal Thus, transamination of branched

chain 2-oxo acids by BCATm may play a specific role in

BCAA conservation which can then be used in protein

synthesis [28] during gestation

It is probable that BCATm plays an important role in the

reamination of branched chain 2-oxo acids because of an

increase in the concentration of glutamate in fetal liver at the

end of pregnancy [29] These data agree with known

nitrogen conservation schemes in pregnancy and with the

important demands on amino-acid supply by fetal growth In

this phase of fetal growth the placental amino-acid uptake is

considerable and seems to be higher than immediately

before birth [29] An increasing capacity for glutamate

absorption by the developing placenta has been

demon-strated This concentrative absorption of glutamate by the

developing placenta is critical for proper fetal development

[30] As shown in Fig 7 there is a high expression of

BCATc and BCATm isoenzymes in placenta that may

contribute to the transamination of BCAA to produce

glutamate and branched chain 2-oxo acids which can be

used by the fetus

This situation is reversed after birth, the activity and

expression of the active form of liver BCATm decreases

dramatically after birth, whereas in other extrahepatic

tissues such as heart, BCATm activity and mRNA

expression increase On the other hand, BCODC activity

increases dramatically in liver and heart during the suckling

period thus increasing the oxidative capacity of BCAA after

birth [20] During postnatal life, we observed the appearance

of an inactive form of the BCATm in adult liver; therefore

BCAA are shuttled to extra-hepatic tissues in the adult rat

thus preventing their oxidation in liver [31] The results

of this study suggest that there is no alternative splicing

of the BCATm gene; the sequence of the cDNA from

liver is the same as that of heart BCATm cDNA [6] It

is possible that some step in the processing of the

BCATm protein is inactive in the adult liver, but is

active in fetal liver Studies in our laboratory are in

progress to elucidate the mechanism of regulation of the

two forms in liver At the present time, we cannot rule

out the possibility that the 43-kDa protein is responsible

for the low BCAT activity in liver, although it has been

asparagine aminotransferase in liver

Although BCATm expression is unresponsive to dietary

protein or hormones (hydrocortisone and glucagon) in

extrahepatic tissues [4], conditions related to cell growth as

in fetal liver [11], growth of hepatocytes in culture [32], and

lactating mammary gland tissue [8,9] stimulates BCATm

activity and expression There is evidence to support the role

of BCAT in cell growth Two yeast proteins have been

shown to function as BCAT [33,34]; mutation of one of

these BCAT homologs produces a short G1 stage indicating

that this protein is involved in cell cycle regulation On

the other hand, the mouse BCATc gene is highly

expressed early in embryogenesis and in several c-myc

based tumors Thus, BCAT may play additional roles in

situations where high cell proliferation takes place and

perhaps the nuclear localization of BCATm in fetal liver

is involved in one of them Further studies are required

to clarify the possible role of BCAT in situations of

accelerated cell proliferation

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

Financial support was from CONACYT 25637M (to A R T.), Me´xico.

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