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180 
Original Article 

Biosci. J., Uberlândia, v. 34, n. 1, p. 180-185, Jan./Feb. 2018 

EFFECT OF TIME OF GESTATION ON FATTY ACID TRANSPORTERS 

MRNA EXPRESSION IN BOVINE PLACENTA 
 

EFEITO DO TEMPO DE GESTAÇÃO EM EXPRESSÃO DE ARNM DE 
TRANSPORTADORES DE ÁCIDOS GRAXOS MRNA EM PLACENTA BOVINOS 

 

Ramiro DESANTADINA
1
; Silvina QUINTANA

2-3
; Mariana Inés RECAVARREN

2
;  

Alejandro Enrique RELLING
4
 

1. Instituto de genética Veterinaria, Concejo Nacional de Ciencia y Técnica y Universidad Nacional de La Plata. La Plata, Buenos Aires, 
Argentina; 2. Laboratorio Bioquímico Fares Taie. Mar del Plata, Buenos Aires, Argentina; 3- Consejo Nacional de Investigaciones 

Científicas y Técnicas (CONICET), Rivadavia 1917, C1033AAJ Buenos Aires, Argentina; 4. Instituto de Genética Veterinaria, Concejo 
Nacional de Ciencia y Técnica y Universidad Nacional de La Plata. La Plata, Buenos Aires, Argentina. Currently at: Department of 

Animal Sciences, The Ohio State University, Ohio. USA. relling.1@osu.edu 
 

ABSTRACT: The objective of the study was to evaluate the effect of time of gestation on fatty acid transporter 
mRNA expression in maternal and fetal bovine placenta. Placentas from twelve cows at different thirds of gestation (n=4 
per third) were sampled at slaughter to measure FATP-1, FATP-4, FABP-1 mRNA concentration in maternal (caruncles) 
and fetal (cotyledons) side. Once the placenta was removed, 1cm2 was dissected and, divided into caruncles and 
cotyledons, stored in sterile tubes, dropped into liquid nitrogen and kept at -80° C until rtPCR analysis. Data were 
analyzed as a complete randomized design with a 3 x 2 factorial arrangement, using the mixed procedure (SAS 9.3) with 
repeated measurements on space. Time of gestation, side of the placenta and their interaction were fixed factors, whereas 
animal was a random factor. There was a time by treatment interaction (P < 0.01) on FATP-1 mRNA expression due to a 
greater mRNA expression in cotyledons on the first third of gestation as compared with the concentration in caruncles. On 
the second and third stages of gestation, the mRNA concentration in cotyledons decreased, reaching a similar 
concentration to that observed in caruncles. Fatty acid transport protein -4 and FABP-1 mRNA concentration were not 
different (P >0.1). We conclude that FATP-1 might play an important role in fatty acid transport during early fetal 
development. 
 

KEYWORDS: Fatty acid binding protein. Fetal programming. Fatty acids. 
 
INTRODUCTION 
 

The n-6 and n-3 fatty acids (FA) are 
essential, therefore cannot be formed de novo by 
mammalian cells. Bell (1995) reports that there is 
little FA passage on bovine placenta. However, all 
n-6 and n-3 accumulated on the fetus must be 
derived from the mother by placenta transfer 
(INNIS, 2005).  

The mechanisms for FA transport across the 
placenta involve several trans-membrane and 
intracellular proteins (CAMPBELL et al., 1996). 
The distribution on different tissues, specificity, and 
functions are known in non-ruminant species 
(NICKERSON et al., 2009) and sheep (ZHU et al., 
2010); however, it is not known how the gene 
expression of these proteins change during the 
length of gestation. Also, there are no studies that 
show their presence on bovine placenta and if they 
change their expression throughout the gestation. 

Therefore the objective of this study was to 
evaluate the presence and amount of mRNA coding 
for fatty acids transport proteins 1 and 4 , FATP-1, 
FATP-4, (SLC27A1 and SLC27A4, respectively) 
and fatty acid binding protein 1 (FABP-1) in the 

fetal and maternal side of the placenta during the 
different thirds of gestation. 
 
MATERIAL AND METHODS 
 

FATP-1, FATP-4, and FABP-1 mRNA 
expression was measured on maternal and fetal size 
of bovine placenta. The experiment was a complete 
randomize designed with a 3 by 2 factorial 
arrangements of the treatments. The main factors 
were stages in gestation (first, second or third) and 
the side of the placenta (maternal- caruncle or fetal- 
cotyledon). 

Placenta tissue was collected from a 
commercial slaughterhouse within 30 minutes of the 
slaughter. Cull cows coming from pasture systems 
were slaughter following the National Service of 
Agrofood Health and Quality (SENASA, Argentina) 
regulations. Based on the size of the placentome 
(combination of cotyledon and caruncle) and length 
of fetus (Table 1, modified from ZEMJANIS, 1970) 
the gestation was divided in three thirds (n=3 per 
third of gestation). From the placentome, a sample 
an area of 1 cm2 was taken with a sterile scalpel 
blade. From that sample the caruncule was separated 

Received: 17/01/17 
Accepted: 05/12/17 



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Biosci. J., Uberlândia, v. 34, n. 1, p. 180-185, Jan./Feb. 2018 

from the cotyledon and each subsample was added 
in a labeled sterile tube and flash frozen using liquid 

N2. Samples were store at– 80°C until analysis.  

 
Table 1. Characteristics of fetus and bovine placenta according to the month of gestation. Modified from 

Zemjanis, 1970.   
Time of gestation Fetal characteristics Placentome size 

2-3 months 10-15 cm. length Up to 1.5 x 1 cm 
4 to 6 months 20 to 55 cm length From  2 x 1,25 cm (day 100) to 4 x 2.5 cm 

(day 180) 

7 to 9 months 60 to 80 cm length,  
Hairs in the tail (day 210), ears 
(day 240) or covering the 
whole body (day 280) 

From  5 x 3 cm (day 210) to 8 x 5 cm (day 
280) 

 
Total RNA was isolated using the TRIzol® 

reagent (Invitrogen-Life Technologies, Carlsbad, 
USA) according to the manufacturer’s protocol. 
RNA preparations were further treated with DNase 
(Qiagen, Hilden, Germany). Quantity and quality of 
RNA was measured using UV spectroscopy 
(Nanodrop Technologies). Complementary DNA 
(cDNA) was synthesized using a reaction mixture 
containing 1,5 µ g of total RNA, random hexamers 
and the MMLV-reverse transcriptase (Invitrogen-
Life Technologies), following the procedure 
suggested by the manufacturer. Negative controls 
omitting the RNA or the reverse transcriptase were 
included and tested in the PCR procedure. 
Complementary DNA of the fetal and maternal 
placenta were subjected to qPCR assays using Eva 
Green as intercalating dye (KAPA FAST, 
Biosystems, Woburn, USA). Quantitative PCR was 
performed in a Rotor Gene Q thermocycler 
(Qiagen). The cycling program consisted of an 
initial denaturation of 2 minutes at 95° C, and 45 
cycles of 15 seconds at 94°C, specific annealing 
temperature 20 seconds and 72°C. After 
amplification, a melting curve analysis was 
performed, which resulted in single product-specific 
melting curve.  In all cases, experiments were done 
in duplicates. 

Negative controls for cDNA synthesis and 
PCR procedures were included in all cases. A list of 
the primers used in PCR protocols, specific 
annealing temperature and product length in each 
case is shown in Table 2.  All primers used in this 
study were designed with Primer Premier Software 
(PREMIER Biosoft International, Palo Alto, USA).  

Relative expression values were calculated 
by the ddCT method (LIVAK; SCHMITTGEN, 
2001). Each of the three targets were analyzed 
separately, and normalized to bovine beta-actin 
(ACTB). 

Quantification of mRNA levels of   FATP-
1, FATP-4 and FABP-1 was performed on fetal and 
maternal placenta.   The amplification efficiency 
was determined for each gene using 10-fold 
dilutions of cDNA. In all assays, standard curves for 
each gene  had a slope between -3.2 and -3.5 and the 
standard deviation between duplicates  was in all 
cases <0.167 as recommended for  qPCR  
(BUSTIN, 2002). 

FABP-4 mRNA expression was evaluated 
using two different sets of primers (Table 2). 
However, FABP-4 mRNA was not detected using 
the described primers and conditions. 

Data was analyzed as a complete 
randomized design with repeated measurements in 
place and a 3x2 factorial arrangement of treatments. 
The repeated measurement in place takes into 
consideration the common variation on the results 
coming from the placentome (cotyledon and 
caruncle from the same cow). The main factors were 
trimester of gestation (first, second or third) and the 
side of the placenta (maternal or fetal). Data was 
analyzed with the Proc Mixed of SAS (9.4). The 
model contained the side of the placenta, the third of 
gestation and their interaction as fixed variables. 
And the cow as random variable. If the value of the 
interaction side and third of gestation was less than 
0.1 the option slice of SAS was used for mean 
separation.  

 
 
 
 
 
 
 
 
 
 
 



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Table 2. Primers used in this study .Sequence, annealing temperature and PCR product length. 

Primer 5`- 3´ Sequence 
Annealing 
temperature 

Product length 
(base pairs) 

FATP-1 FW AGCCTGGTCAAGTTCTGTTCTGGA 60 °C 142 

FATP-1 RV AGAAGAGTCGATCATCCATGCCCT   

FATP-4 FW CTACTCAAACAGCGTGGCCAACTT 60 °C 97 

FATP-4 RV ACCCACAAACTCATTGCGGTTCTC   

FABP-1 FW CAAGTACCAAGTCCAGACCCAG 55°C 113 

FABP-1 RV GCACGATTTCCGACACCC   

ACTB FW GCCAGGTCATCACCATCGG 58°C 191 

ACTB RV CAGCACCGTGTTGGCGTAG   

FABP-4 1 FW 

FABP-4 1 RV 

ATGAAAGAAGTGGGCGTGGGCTTT 

GCTCTTGACTTTCCTGTCATCTGG  
Undetermined 189 

FABP-4 2FW 

 FABP-4 2RV 

AGATGAAGGTGCTCTGGT and 

CTCATAAACTCTGGTGGC 
Undetermined 130 

 
RESULTS 
 

FATP-1 mRNA expression shows a side by 
third of gestation interaction (P = 0.07, Figure 1). 
This interaction is mainly due to a greater FATP-1 
mRNA expression during the first third of gestation 
on the fetal side of the placenta compared with the 
maternal side (P <0.01). On the second third of 
gestation, the expression of fetal FATP-1 mRNA 
decreases in relationship with the first third and 

remains greater than the maternal side (P <0.05). By 
the last third of gestation there is no difference 
between the maternal and the fetal FABP-1 mRNA 
expression (P >0.1). 

There is no effect on FATP-4 (Figure 2) and 
FABP-1 (Figure 3) mRNA expression due to side (P 
> 0.05), a length of gestation (P >0.05) or 
interaction side by length of gestation (P > 0.1).   

 
 

 

 
 
Figure 1. Relative concentration of Fatty acid Transport Protein (FATP) 1 mRNA in caruncle or cotyledon a 

different thirds of gestation on bovine placenta. Data is presented as LS means and SEM. P value for 
time of gestation <0.01, for site (caruncle or cotyledon) > 0.1, and for the interaction time by site = 
0.07. Slice option of SAS 9.4 was used for mean separation in which **P<0.01; * P <0.05 

 



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Figure 2. Relative concentration of Fatty acid Transport Protein (FATP) 4 mRNA in caruncle or cotyledon at 

different thirds of gestation on bovine placenta. Data is presented as LS means and SEM. P value for 
time of gestation >0.1, for site (caruncle or cotyledon) > 0.1, and for the interaction time by site > 0.1. 

 

 
Figure 3. Relative concentration of Fatty acid Binding Protein (FABP) 1mRNA in caruncle or cotyledon at 

different thirds of gestation on bovine placenta. Data is presented as LS means and SEM. P value for 
time of gestation >0.1, for site (caruncle or cotyledon) > 0.1, and for the interaction time by site > 
0.1. 

 
DISCUSSION 

 
As we are aware this is the first publication 

that shows mRNA expression of FATP-1, FATP-4 
and FABP-1 during different stages of gestation and 
in different parts of the bovine placentome. Changes 
on mRNA expression of a particular gene is not 
always associated with changes in protein 
concentration for that particular gene. However, 
changes in mRNA expression give a first insight of 
biological process occurring in the tissue.  

It is known that essential fatty acids cannot 
be synthesize and therefore they are obtained from 
the diet. During fetal development these fatty acids 
are provided by the dam from the placental. Some of 
these fatty acids, such as arachidonic acid (AA) and 
docosahexaenoic acid (DHA), are very important in 
the development of the nervous tissue in all 
mammals (INNIS, 2005); therefore, the passage of 

these fatty acids through the placenta is a process 
that may have a controlled regulatory mechanism of 
action (LAURITZEN et al., 2016).  Bell (1995) 
mentions that the passage of fatty acids through the 
bovine placenta is low. However, the finding of 
mRNA of fatty acids transporters and that the 
expression of them have different patterns during 
gestation may show that this low passage of fatty 
acids has a great control. Our results show that there 
are changes only in FATP-1 expression and not in 
FATP-4 or FABP-1. This may be due to affinity to 
specific fatty acid which is important at a particular 
stage of gestation (first and second third) but not 
that important in other (last third of gestation). 
Increase in FABP gene expression was observed in 
specific tissues that need a particular fatty acid, such 
as in cold-acclimated ducks (BÉNISTANT, et al., 
1998) or in pregnant ewes (ZHU et al., 2010). The 
affinity of the FABP to the fatty acids depends on 



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many factors such as specie, tissue, number of 
double bond and carbon length of the fatty acids 
(HANHOFF et al., 2002). In humans, there is a 
mayor affinity of FABP-1 to essential 
polyunsaturated fatty acids than to no essential 
saturated fatty acids. (CAMPBELL et al., 1996; 
LAURITZEN et al., 2001). However there are no 
studies in bovine that evaluate the affinity of FABPs 
and essential fatty acids. 

As stated in the materials and methods, with 
the described setting we were not able to detect 
FABP-4 mRNA concentration. It is possible that we 
were not able to find the right conditions or primers, 
but it is also possible that FABP-4 is not express in 
bovine placenta.    

CONCLUSION 
 
Only FATP-1 mRNA expression changes in 

bovine placentome, having a greater expression on 
the fetal side comparing with the maternal side on 
early gestation, but the difference decreases in the 
second half of gestation and are similar at the end of 
the gestation. 

  
ACKNOWLEDGEMENTS 

This work was partially financially 
supported by the PICT-2008-00314, Metabolismo 
de Acidos Grasos en Rumiantes (ANPCyT) 

 
 

RESUMO: O objetivo do estudo foi avaliar o efeito do tempo de gestação na expressão de mRNA de 
transportador de ácidos graxos em placenta bovina materna e fetal. Foram colhidas amostras de placentas de 12 vacas em 
diferentes terços da gestação (n = 4 por terço) no abatedouro para medir a expressão de mRNA de FATP-1, FATP-4, 
FABP-1 no lado materno (carúnculos) e fetal (cotilédones). Uma vez que a placenta foi removida, 1 cm2 foi dissecado e, 
dividido em carúnculos e cotilédones, armazenado em tubos estéreis, caiu em nitrogenio líquido e mantido a -80 ° C até a 
análise rtPCR. Os dados foram analisados como um delineamento inteiramente casualizado com esquema fatorial 3 x 2, 
utilizando o procedimento misto (SAS 9.3) com medidas repetidas no espaço. O tempo de gestação, o lado da placenta e 
sua interação foram fatores fixos, enquanto que o animal foi um fator aleatório. Houve um tempo de interação do 
tratamento (P <0,01) na expressão de mRNA de FATP-1 devido a uma maior expressão de mRNA em cotilédones no 
primeiro terço da gestação em comparação com a concentração em carúnculas. No segundo e terceiro terços da gestação, a 
expressão de mRNA nos cotilédones diminuiu, atingindo uma expressão semelhante à observada em carúnculas. A 
proteína de transporte de ácidos graxos 4 e a  expressão de mRNA de FABP-1 não foram diferentes (P> 0,1). Concluímos 
que a FATP-1 poderia desempenhar um papel importante no transporte de ácidos graxos durante o desenvolvimento fetal 
precoce. 
 

PALAVRAS-CHAVE: Proteína de ligação a ácidos graxos. Programação fetal. Acidos graxos. 
 

 
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