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Association Analysis of Polymorphism of FGFR1 and EBP41L5 Genes with Kidding Performance of Goats

PJZ_55_3_1373-1381

Association Analysis of Polymorphism of FGFR1 and EBP41L5 Genes with Kidding Performance of Goats

Zhao Fulin1,2, Liang Chen2, Tao Lin1, Jiang Yanting3, Ouyang Yina3,

Hong Qionghua3* and Chu Mingxing1*

1Key Laboratory of Animal Genetics, Breeding and Reproduction of Ministry of Agriculture and Rural Affairs, Institute of Animal Science, Chinese Academy of Agricultural Sciences, Beijing 100193.

2College of Animal Science, Shanxi Agricultural University, Taigu 030801.

3Yunnan Animal Science and Veterinary Institute, Kunming 650224.

Zhao Fulin and Liang Chen contributed equally to this work.

ABSTRACT

This study aimed to analyze the association between single nucleotide polymorphisms (SNPs) in the FGFR1 and EBP41L5 genes and kidding performance of goats. Mass ARRAY®SNP typing technology was applied to genotype the SNPs of FGFR1 and EBP41L5 genes, of which the genetic characteristics of Yunshang Black goat (YS, n=544), Jining Grey goat (JN, n=133) and Liaoning Cashmere goat (LN, n=91) were explored. Then the association was analyzed between FGFR1 and EBP41L5 and kidding performance (litter size, litter weight at birth, litter weight at weaning) in different goats. Population genetics statistics showed that FGFR1 gene g. 12120297A> G and EPB41L5 gene g. 64237881A> C were low polymorphisms in the three populations (PIC< 0.25); EPB41L5 gene g. 64266710G> C and g. 64266715G> C were moderately polymorphic in Yunshang Black goat and Liaoning Cashmere goat (0.25<PIC<0.5), and in Jining Grey goat was low polymorphism (PIC< 0.25). The χ2 test indicated that EPB41L5 gene g. 64237881A> C locus was under Hardy-Weinberg disequilibrium in Jining grey goat (P< 0.05), and was under Hardy-Weinberg equilibrium in Yunshang Black goat and Liaoning Cashmere goat (P> 0.05). FGFR1 gene g. 12120297A> G, EPB41L5 gene g. 64266710G> C, g. 64266715G> C were under Hardy-Weinberg equilibrium in Yunshang Black goat, Jining Grey goat and Liaoning Cashmere goat (P> 0.05). Association analysis indicated that there were no significant correlation between FGFR1 gene g. 12120297A> G locus and EPB41L5 gene g. 64266715G> C locus and litter size, litter weight at birth and weaning (P> 0.05). There were significant correlation between EPB41L5 gene g. 64237881A> C and g. 64266710 G> C and litter size (P< 0.05), and were no significant correlation and litter weight at birth (P> 0.05), there were no significant correlation between EPB41L5 gene g. 64237881A> C and litter weight at weaning (P> 0.05), there were significant correlation between EPB41L5 gene g. 64266710C> G and litter weight at weaning (P< 0.05). Therefore, these results suggested that EPB41L5 gene g. 64237881A> C, g. 64266710 G> C loci were suitable as molecular markers for litter size in YS, and g. 64266710G> C locus was suitable as a selection marker for litter weight at weaning.


Article Information

Received 24 July 2021

Revised 18 October 2021

Accepted 25 October 2021

Available online 01 June 2022

(early access)

Published 14 April 2023

Authors’ Contribution

ZF contributed to the idea of this article, completed data analysis and wrote the article. CM and LC contributed to revisions of the manuscript.TL, JY, OY and HQ completed goat sampling and data collection.

Key words

Goat, Litter size, Litter weight, FGFR1 gene, EPB41L5 gene

DOI: https://dx.doi.org/10.17582/journal.pjz/20210724140723

* Corresponding author: [email protected], [email protected]

0030-9923/2023/0003-1373 $ 9.00/0

Copyright 2023 by the authors. Licensee Zoological Society of Pakistan.

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).



INTRODUCTION

In the development process of human civilization, goats provided humans with the main means of living such as meat, milk, skin and hair, and played an important role in human agricultural civilization and economic development. The kidding traits of goats were closely related to the reproduction speed and scale of their populations. They were an important factor that affects the economic benefits of goat breeding and were also important economic traits of goat breeding (Zheng et al., 2021). However, due to the low heritability of kidding traits, it was relatively slow to use traditional breeding methods to get more obvious genetic improvement of kidding traits, while molecular breeding technology can quickly increase the kidding rate of goats by controlling the major genes of kidding traits. Many scientists have conducted a lot of research on the relationship between single nucleotide polymorphisms and goat kidding traits, hoping to find genes that can be used to improve goat kidding traits (Zhu et al., 2021). Fibroblast growth factor receptor 1 (FGFR1) belongs to the fibroblast growth factor receptors (FGFRs) family, which includes a total of 4 receptor protein tyrosine kinases FGFR (1-4) (Qin et al., 2019). Each receptor contains an extracellular domain composed of three immunoglobulin (Ig)-like domains (domains I to III), a transmembrane domain, and an intracellular tyrosine kinase structure 2 (Turner and Grose, 2010). Fibroblast growth factors (FGFs) combined with FGFRs induce dimerization and phosphorylation of specific cytoplasmic tyrosine residues, and activate cytoplasmic signal transduction pathways (Carter et al., 2015). Studies have shown that genetic variation in the FGF/FGFR pathway is significantly related to the risk of ovarian cancer, treatment response and survival rate (Meng et al., 2014; Haugsten et al., 2010). Most studies have shown that the FGF/FGFR pathway plays a role in ovarian diseases, and it can be seen that the genes on this pathway are expressed in the ovaries. Erythrocyte membrane protein band 4.1 like 5 (EPB41L5) is a member of the band 4.1 superfamily (Hirano et al., 2008), locate on chromosome 2. It has a FERM domain at its N terminus and an actin-binding domain at its C terminus (Gamblin et al., 2018), which was related to cell movement. In addition, it can also participate in the development process of the body and can regulate the expression of downstream cadherin E (E-cadherin) in the process of epithelial cell-mesenchymal transition (EMT transformation) induced by transforming growth factor-β (TGF-β) (Li et al., 2019), the EMT transformation process played an important role in embryonic development, chronic inflammation, tissue reconstruction, cancer metastasis, and various fibrotic diseases. At the same time, EPB41L5 directly controlled the contractility and focal adhesion of actin, and regulated cell proliferation and migration (Hashimoto et al., 2016). The role of abnormal expression of EPB41L5 in malignant tumors has gradually been confirmed (Chen et al., 2019). It can be seen that the FGF/FGFR pathway has a certain influence in ovarian diseases. EPB41L5 was involved in embryonic development, so these two genes may be related to goat kidding performance. Based on the results of re-sequencing of Yunshang black goat (The Yunshang black goat is the first meat purpose black goat breed in China, which is bred from the Yunling goat as the dam and the Nubi goat as the sire (Tao et al., 2020a, b)) in the early stage of our laboratory, it is speculated that FGFR gene and EPB41L5 gene may have some influence on kidding performance. A MassARRAY® SNP typing technology was used to detect the genotypes of candidate genes and analyze the association between their polymorphisms and litter size traits. This study aimed to analyze the genetic polymorphisms of FGFR and EPB41L5 in Yunshang black goat, Jining grey goat and Liaoning cashmere goat population and their correlation with kidding performance, and provide more information about genetic markers for improving the prolificacy of goat.

MATERIALS AND METHODS

Animal preparation and sample collection

A total of 768 goats (2~5 years old) were employed in this study, including 544 Yunshang black goats, 133 Jining grey goats, and 91 Liaoning cashmere goats. The higher prolificacy breeds included in this study was Jining Grey goats, and Liaoning Cashmere goats was regarded as lower prolificacy breeds (Wang et al., 2020; Chu et al., 2013). The breeding conditions of all experimental goats were the same. Yunshang Black goat had records of the number of litters born at least one litter, and some had records of litter weight at birth and litter weight at weaning (3 months old). Jugular blood samples from 768 goats of the three breeds were collected into EDTA-coated tubes and stored at –20°C until used for DNA isolation.

Extraction of blood DNA

Samples of test goat were processed with the phenol–chloroform method for DNA isolation. The concentration of DNA samples were detected by using Nano Drop2000, and the quality of DNA samples were detected by using 1.5% agarose gel electrophoresis.

Genotyping

FGFR1 gene g. 12120297 A>G, EPB41L5 gene g. 64237881 A>C, g. 64266710 G>C and g. 64266715 G>C sites were used to detect by Sequenom MassARRAY® SNP typing technology. The related primer information was shown in Table I. The typing sample is DNA, the required amount of each sample is 20 μL, and the DNA concentration is 40~80 ng/μL.

Phylogenetic analysis

A phylogenetic tree of EPB41L5 gene coding sequence in fifteen species (goat, pig, alpaca, human, horse, sheep, dog, cow, Norway rat, mouse, monkey, chicken, duck, fish and cat) were constructed with MEGA software. Sequences were obtained from the NCBI (https://www.ncbi.nlm.nih.gov/) Reference (NC_030809.1, NC_010457.5, NW_021964164.1, NC_000002.12, NC_009161.3, NC_056055.1, NC_051823.1, NC_037329.1, NC_051348.1, NC_000067.7, NC_041765.1, NC_052538.1, NC_051778.1, NC_007120.7, NC_018732.3, respectively). Prediction of the physical and chemical properties of EPB41L5 protein was performed using ProtParam. The secondary structure of EPB41L5 was analyzed using SOPMA. Prediction of the mRNA Structure of EPB41L5 was performed using RNAFOLD.

Statistical analysis

Based on genotyping data, genotype frequency, allele frequency, polymorphic information content (PIC), heterozygosity (He) and effective allele number (Ne) were calculated by using Microsoft Excel 2020 software. Hardy-Weinberg equilibrium test was carried out by Chi-square test. The one-way ANOVA was performed by IBM SPSS Statistics 22.0 software, and the LSD method was used for multiple comparisons. The correlation analysis between goat genotype and kidding phenotype data was carried out, and all data were expressed as mean±standard error.

RESULTS

Population genetic analysis of SNPs in FGFR1 and EPB41L5

The genotyping results showed that one SNP in FGFR1 (g.12120297 A>G) and three SNPs in EPB41L5 (g.64237881 A>C, g. 64266710 G>C and g. 64266715 G>C) were detected in all three breed of Yunshang Black goat, Jining Grey goat and Liaoning Cashmere goat. Two genotypes at FGFR1 gene g.12120297 A>G locus, AA and GA, were detected in 759 individuals with a detection rate of 98.8%. Three genotypes at EPB41L5 gene g. 64237881 A>C locus, AA, CC and CA, were detected in 756 individuals with a detection rate of 98.4%. The EPB41L5 g.64266710 C>G and g.64266715 G>C loci contained three genotypes, CC, GG and GC. The locus g.64266710 C>G was detected in 762 individuals with a detection rate of 99.2%, and the locus g.64266715 G>C in 748 individuals with a detection rate of 97.4% (Fig. 1).

 

It can be seen from Table II that the genotype frequency and gene frequency of EPB41L5 gene g.64237881 A>C, g.64266710 G>C and g.64266715 G>C locus differs between the high- and low-reproduction goat populations to a very significant level (P< 0.01). The dominant genotype of EPB41L5 gene g.64237881A>C locus in the high and low-reproduction populations was AA, and the dominant allele is A; the dominant genotype of EPB41L5 gene g. 64266710 G> C and g. 64266715 G> C locus in the high- and low-reproduction populations were GG, and the dominant allele was G. Population genetics statistics showed that there was a genetic polymorphism at FGFR1 gene g. 12120297 A> G locus in Yunshang Black goat, but there were no gene mutations in Jining Grey goat and Liaoning Cashmere goat. The FGFR1 gene g. 12120297A> G and EPB41L5 gene g. 64237881A> C were low polymorphisms in the three population (PIC< 0.25); EPB41L5 gene g. 64266710G> C and g. 64266715G> C were moderately polymorphic in Yunshang Black goat and Liaoning Cashmere goat (0.25< PIC< 0.5), and in Jining Grey goat were low polymorphism (PIC< 0.25). The χ2 test indicated that EPB41L5 gene g. 64237881A> C locus was under Hardy-Weinberg disequilibrium in Jining Grey goat (P< 0.05), and was under Hardy-Weinberg equilibrium in Yunshang Black goat and Liaoning Cashmere goat (P> 0.05). FGFR1 gene g. 12120297A> G, EPB41L5 gene g. 64266710G> C, g. 64266715G> C were under Hardy-Weinberg equilibrium in Yunshang Black goat, Jining Grey goat and Liaoning Cashmere goat (P> 0.05).

Association analysis between candidate loci and reproductive performance

Association analysis indicated that there were no significant correlations between FGFR1 gene g.12120297A>G locus and EPB41L5 gene g.64266715G>C locus and litter size, litter weight at birth and weaning (P> 0.05). There was significant correlation between EPB41L5 gene g.64237881A>C and g.64266710 G>C and litter size (P< 0.05), and there was no significant correlation between the two loci and litter weight at birth (P> 0.05). There was no significant correlation between EPB41L5 gene g.64237881A>C and litter weight at weaning (P> 0.05), there were significant correlation between EPB41L5 gene g.64266710C>G and litter weight at weaning (P< 0.05).

Construction of phylogenetic tree of EPB41L5 gene and other animal species

A phylogenetic tree of EBP41L5 gene coding sequence for other animal species was constructed. The results showed that there was the highest homology between goats and sheep, and there was the higher similarity between goats and cattle, and the sequences of the other species showed relatively large differences between them (Fig. 2).

 

Table I. Primer sequences.

Locus

Classification

Sequences (5’-3’)

FGFR1

g. 12120297 A> G

F

ACGTTGGATGTGGTTTTAGGCAAGCCACTG

R

ACGTTGGATGGGTTGGGTTTGTCCTTGTCC

E

GTCCTTGTCCAGCCCGA

EPB41L5

g. 64237881 A> C

F

ACGTTGGATGTACCTTTAGAGCAGACCCAC

R

ACGTTGGATGAAATGAGAACACTGTGCCCG

E

TGTTCGCATCAGAGCC

EPB41L5

g. 64266710 G> C

F

ACGTTGGATGGCATGTGAAGGAGATCTCTG

R

ACGTTGGATGATGGAAAGCAGTCCTGTGCC

E

TGCCAGCTCCTCACCCCAA

EPB41L5

g. 64266715 G> C

F

ACGTTGGATGGCATGTGAAGGAGATCTCTG

R

ACGTTGGATGATGGAAAGCAGTCCTGTGCC

E

CTGTGCCAGCTCCTCAC

 

Note: F, Upstream primer; R, Downstream primer; E, Extension primer.

 

Table II. Genotype frequency and allele frequency of FGFR1 and EPB41L5 genes in high and low-reproduction goat breeds.

Locus

Genotype

Genotype frequency

Chi-square test (P value)

Allele

Gene frequency

Chi-square test (P value)

High fertility population

Low fertility population

High fertility population

low fertility population

FGFR1

g. 12120297 A> G

AA

1.00 (n=133)

1.00 (n=90)

-

A

1.00

1.00

-

GA

0.00 (n=0)

0.00 (n=0)

G

0.00

0.00

EPB41L5

g. 64237881 A> C

AA

0.89 (n=115)

0.67 (n=57)

0.00

A

0.94

0.82

9.60×10-5

CC

0.01 (n=1)

0.04 (n=3)

C

0.06

0.18

CA

0.10 (n=13)

0.29 (n=25)

EPB41L5

g. 64266710 G> C

CC

0.02 (n=3)

0.06 (n=6)

0.00

C

0.10

0.22

0.00

GG

0.82 (n=107)

0.63 (n=57)

G

0.90

0.78

GC

0.16 (n=20)

0.31 (n=28)

EPB41L5

g.64266715 G> C

CC

0.03 (n=3)

0.10 (n=8)

1.25×10-5

C

0.12

0.31

1.94×10-6

GG

0.79 (n=100)

0.48 (n=40)

G

0.88

0.69

GC

0.18 (n=23)

0.42 (n=35)

 

Note: P< 0.05 means the difference is significant; P< 0.01 means the difference is extremely significant.

 

 

Physical and chemical properties of EPB41L5 protein

It can be seen from Table V that the molecular weight, formula, total number of atoms, instability index, aliphatic index and grand average of hydropathicity of the protein before and after the mutation have happened (Table V). It can be seen from the figure that the hydrophilic amino acids are more than the hydrophobic amino acids before and after EPB41L5 mutation (Fig. 3A, 3B). Therefore, the protein was hydrophobic before and after the mutation, but grand average of hydropathicity has changed. It can be seen that the physicochemical properties of the protein are changed due to the mutation of the three sites, which may cause the function of the protein to change, thereby affecting the kidding traits of the Yunshang Black goat.

 

Table III. Population genetic analysis of candidate loci in three goat breeds.

Locus

Breeds

Genotype frequency

Allele frequency

PIC

He

Ne

P

FGFR1

g. 12120297 A> G

AA

AG

A

G

YS (n=536)

0.95 (n=507)

0.05 (n=29)

0.97

0.03

0.06

0.06

1.06

0.52

JN (n=133)

1.00 (n=133)

0.00 (n=0)

1.00

0.00

0.00

0.00

1.00

-

LN (n=90)

1.00 (n=90)

0.00 (n=0)

1.00

0.00

0.00

0.00

1.00

-

EPB41L5

g. 64237881 A> C

AA

CC

CA

C

A

YS (n=542)

0.83 (n=453)

0.01 (n=3)

0.16 (n=86)

0.08

0.92

0.14

0.15

1.17

0.62

JN (n=129)

0.97 (n=115)

0.02 (n=1)

0.01 (n=13)

0.03

0.97

0.06

0.06

1.06

3.4×10-30

LN (n=85)

0.67 (n=57)

0.04 (n=3)

0.29 (n=25)

0.18

0.82

0.25

0.30

1.42

0.90

EPB41L5

g. 64266710 G> C

CC

GG

GC

C

G

YS (n=541)

0.07 (n=35)

0.54 (n=293)

0.39 (n=213)

0.26

0.74

0.31

0.38

1.63

0.65

JN (n=130)

0.03 (n=3)

0.82 (n=107)

0.15 (n=20)

0.10

0.90

0.16

0.18

1.22

0.10

LN (n=91)

0.06 (n=6)

0.63 (n=57)

0.31 (n=28)

0.22

0.78

0.28

0.34

1.52

0.33

EPB41L5

g.64266715 G> C

CC

GG

GC

C

G

YS (n=539)

0.04 (n=23)

0.32 (n=342)

0.64 (n=174)

0.20

0.80

0.27

0.32

1.47

0.88

JN (n=126)

0.03 (n=3)

0.79 (n=100)

0.18 (n=23)

0.12

0.88

0.19

0.21

1.27

0.24

LN (n=83)

0.10 (n=8)

0.48 (n=40)

0.42 (n=35)

0.31

0.69

0.34

0.43

1.75

0.93

 

Note: PIC, HE and NE represent polymorphic information content, heterozygosity and effective number of alleles, respectively; numbers in the parentheses represent the number of detected sheep of each genotype; YS, JN and LN represent Yunshang Black goat, Jining Grey goat, Liaoning Cashmere goat, respectively; P> 0.05 indicates the locus was under Hardy-Weinberg equilibrium; P< 0.05 indicates the locus was under Hardy-Weinberg disequilibrium.

 

Table IV. The effect of FGFR1 and EPB41L5 on kidding performance of Yunshang Black goat (mean ± standard error).

Locus

Genotype

Number of kidding

Birth weight, kg

Weaning weight, kg

FGFR1

g. 12120297 A> G

AA

2.03±0.02

(n=507)

6.98±0.08

(n=339)

35.95±0.43

(n=339)

GA

2.18±0.01

(n=29)

7.20±0.30

(n=25)

36.60±1.66

(n=25)

EPB41L5

g. 64237881 A> C

AA

2.10±0.02a

(n=453)

6.97±0.09

(n=321)

35.74±0.45

(n=321)

CC

2.33±0.33ab

(n=3)

6.79±0.22

(n=2)

39.89±1.40

(n=2)

CA

1.88±0.51b

(n=86)

7.02±0.16

(n=47)

36.84±7.47

(n=47)

EPB41L5

g. 64266710 G> C

CC

2.24±0.09a

(n=35)

7.63±0.40

(n=19)

38.45±2.03a

(n=19)

GG

2.07±0.03a

(n=293)

6.97±0.10

(n=208)

36.43±0.56ab

(n=208)

GC

1.95±0.36b

(n=213)

6.90±0.13

(n=143)

34.76±0.61b

(n=143)

EPB41L5

g.64266715 G> C

CC

2.18±0.06

(n=23)

7.50±0.33

(n=22)

36.34±1.30

(n=22)

GG

2.00±0.03

(n=342)

7.02±0.10

(n=196)

36.41±0.59

(n=196)

GC

2.07±0.04

(n=174)

6.83±0.13

(n=149)

35.10±0.63

(n=149)

 

Note: Numbers in the parentheses next to litter size represent the number of sheep of each genotype; Different lower-case letters in the same group indicate significant difference (P < 0.05).

 

Table V. The physicochemical properties of protein before and after EPB41L5 mutation.

Physical and chemical properties

Before mutation

After mutation

Number of amino acids

724

724

Molecular weight

80349.07

80378.03

Theoretical pI

6.45

6.45

negatively charged residues

(Asp + Glu)

96

96

Positively charged residues

(Arg + Lys)

91

91

Formula

C3542H5658 N1000O1093S19

C3540H5653 N1003O1094S19

Total number of atoms

11312

11309

Instability index

51.79 (Unstable protein)

52.17 (Unstable protein)

Aliphatic index

82.57

82.03

Grand average of hydropathicity (GRAVY)

-0.460

-0.471

 

Prediction of the protein and mRNA structure

For two missense mutations found in EPB41L5 of goat, the secondary structure of the protein and mRNA before and after the mutation at g. 64266710 G> C, g.64266715 G> C and g. 64237881 A>C were predicted, respectively. It can be seen that alpha helix, extended strand, beta turn and random coil in the secondary structure of the protein have changed before and after the mutation (Table VI). The results showed that the secondary structure of the protein (Fig. 4A, B) and mRNA (Fig. 4C, D) did change significantly after the mutation. And its minimum structural free energy is reduced, from -716.13kJ mol-1 to -719.88.kJmol-1.

 

 

Table VI. The secondary protein structures before and after EPB41L5 mutation.

The secondary protein structures

Before mutation

After mutation

Alpha helix(Hh)

31.91%

33.98%

Pi helix(Ii)

0.00%

0.00%

Beta bridge(Bb)

0.00%

0.00%

Extended strand (Ee)

16.30%

14.50%

Beta turn(Tt)

3.18%

2.90%

Bend region(Ss)

0.00%

0.00%

Random coil(Cc)

48.62%

48.62%

 

DISCUSSION

Fibroblast growth factor receptor 1 (FGFR1) was located on goat chromosome 27. The binding of FGF led to FGFR dimerization and conformational changes, which phosphorylate the tyrosine kinase domain. Fibroblast growth factor receptor substrate 2 was a crucial adaptor protein in the FGFR signaling cascade. The phosphorylated tyrosine residues in turn became its docking site, and its phosphorylation led to adaptor proteins such as the recruitment of SOS and GRB2, activated downstream MAPK, PI3K/AKT and other signaling pathways (Datta et al., 2017). The physiological roles of FGF/FGFR signaling pathway included embryonic development, wound healing, angiogenesis and tissue crosstalk (Heinzle et al., 2011). In addition, the FGF/FGFR signaling pathway was essential for cell proliferation, migration, differentiation, apoptosis and survival (Dieci et al., 2013). Studies have shown that abnormal FGF/FGFR signals are closely related to the pathogenesis of a variety of cancers, including lung cancer, gastric cancer, breast cancer, ovarian cancer, urothelial cancer and endometrial cancer (Dorey and Amaya, 2020). Erythrocyte membrane protein band 4.1 like 5 (EPB41L5) also known as BE37, YMO1, had a molecular weight of 85 kD. EPB41L5 discovered for the first time in November 2007, which was a protein related to cytoskeleton and cell movement (Rhim et al., 2012), and it was widely expressed in mammalian embryonic mesoderm and endoderm epithelial tissues (Tepass, 2009). It had a FERM domain at their N-terminus, but lacks an actin binding site at their C-terminus (Hashimoto et al., 2016). EPB41L5 was involved in the regulation of many important biological processes, included the cellular actin skeleton, cell adhesion molecules, EMT, basement membrane formation, cell polarity formation and other processes. Research has shown that the FERM domain contained in EPB41L5 can cross-link with the myosin protein containing the myosin tail homology 4 (MyTH4) domains. Involved in regulating the formation of pseudopodia and cell movement, and can be combined with the cytoskeleton protein Talinl, PTK, etc., (Sordella, 2003). Hirano’s (Hirano et al., 2008) research showed that EPB41L5 overexpression can reduce Ecadherin on the cell membrane surface through the action of its FERM domain, thereby promoting the EMT process. Gosens et al. (2007) found that CRB-MPP5-EPB41L5 complex can regulate a variety of cell adhesion factors, it played an important role in the tight junctions between cells and in the formation of cell polarity, and was closely related to epithelial cell polarity and basement membrane formation. In addition, experiments have shown that EPB41L5 can affect the expression of cell adhesion molecules and skeletal proteins in embryonic endoderm epithelial cells (Hirano et al., 2008). At the same time, EPB41L5 can regulate cell polarity and was an essential protein for basement membrane formation and embryonic gastrulation (Takakuwa et al., 1986). In summary, the expression of EPB41L5 is related to embryonic development and may affect goat kidding traits. The genotype frequency and allele frequency of EPB41L5 reached extremely significant levels between the high- and low-reproduction goat populations (P< 0.01). Therefore, it is speculated that its mutation may have a certain impact on fecundity, and it needs to be further verified by experiments. Association analysis showed that there were significant correlation between EPB41L5 gene g.64237881A> C and g.64266710G> C and number of litter size (P< 0.05). There were significant correlation between EPB41L5 gene g. 64266710C> G and litter weight at weaning (P< 0.05). It indicates that EPB41L5 gene g. 64237881A> C and g. 64266710G> C may be critical sites for the number of litter size and litter weight at weaning. Therefore, in order to provide a reference for goat molecular breeding, this study aimed to analyze the genetic polymorphisms of FGFR and EPB41L5 in Yunshang Black goat, Jining Grey goat and Liaoning Cashmere goat population and their association with kidding performance.

Correlation analysis showed that g. 64237881A> C, g. 64266710G> C of EPB41L5 gene may affect kidding performance. In order to further explore the changes in the structure of the protein before and after the mutation of g. 64237881A> C and g. 64266710G> C, two sites were analyzed by bioinformatics. Bioinformatics analysis of EPB41L5 gene showed that the gene conforms to the laws of biological evolution. Before and after the mutation, the physical and chemical properties, the secondary structure of the protein and mRNA were changed. Therefore, it is possible that mutations in the site may result in changes in the structure of the protein, which in turn may result in changes in function. Therefore, g. 64237881A> C, g. 64266710G> C of EPB41L5 gene may be the key site for litter size and litter weight at weaning.

CONCLUSIONS

There was significant correlation between EPB41L5 gene g. 64237881A> C and g. 64266710G> C and litter size (P< 0.05). There was significant correlation between EPB41L5 gene g. 64266710C> G and litter weight at weaning (P< 0.05). Therefore, these results suggested that the EPB41L5 gene g. 64237881A> C and g. 64266710G> C loci are suitable as a molecular marker for litter size in Yunshang Black goat, and g. 64266710G> C locus is suitable as a selection marker for litter weight at weaning.

ACKNOWLEDGMENTS

This research was financially supported by China Agriculture Research System of MOF and MARA (CARS-38), Major Science and Technology Project of Yunnan Province (202102AE090039), the Basic Research Foundation Key Project of Yunnan Province (202001AS070002), Agricultural Science and Technology Innovation Program of China (CAAS-ZDRW202106 and ASTIP-IAS13), Key Research and Development Project of Shanxi Province (201903D211008), Shanxi Province 1331 Project Key Disciplines of Animal Sciences (J201911301), Shanxi Agricultural University Doctoral Research Initiation Project (2021BQ04).

Statement of conflict of interest

All authors have declared no conflicts of interest.

REFERENCES

Carter, E.P., Fearon, A.E. and Grose, R.P., 2015. Careless talk costs lives: Fibroblast growth factor receptor signalling and the consequences of pathway malfunction. Trends Cell Biol., 25: 221-233. https://doi.org/10.1016/j.tcb.2014.11.003

Chen, X., Shi, Y.H., Guo, X.Y., Hu, L.J. and Zhu, C.J., 2019. EPB41L5 mRNA expression in esophageal cancer tissues and cells and its influence on the invasion and metastasis of esophageal cancer cells. Shandong med. J., 59: 29-32.

Chu, M.X., Yan, Y., Wang, P.Q., Guligena, Yang, H.G., Hao, G., Yu, J.G., Tang, Q.Q., Feng, T., Cao, G.L., Huang, D.W., Di, R., Liu, Q.Y. and Li, N., 2013. Polymorphism of AA-NAT gene and its relationship with litter size of Jining Grey goat of China. Anim. Sci. Pap. Rep., 31: 15-26.

Datta, J., Damodaran, S., Parks, H., Ocrainiciuc, C., Miya, J., Yu, L., Gardner, E.P., Samorodnitsky, E., Wing, M.R., Bhatt, D., Hays, J., Reeser, J.W. and Roychowdhury, S., 2017. Akt activation mediates acquired resistance to fibroblast growth factor receptor inhibitor BGJ398. Mol. Cancer Ther., 16: 614-624. https://doi.org/10.1158/1535-7163.MCT-15-1010

Dieci, M.V., Arnedos, M., Andre, F. and Soria, J.C., 2013. Fibroblast growth factor receptor inhibitors as a cancer treatment: From a biologic rationale to medical perspectives. Cancer Discov., 3: 264-279. https://doi.org/10.1158/2159-8290.CD-12-0362

Dorey, K. and Amaya, E., 2010. FGF signalling: Diverse roles during early vertebrate embryogenesis. Development, 137: 3731-3742. https://doi.org/10.1242/dev.037689

Gamblin, C.L., Parent-Prevost, F., Jacquet, K., Biehler, C., Jette, A. and Laprise, P., 2018. Oligomerization of the FERM-FA protein Yurt controls epithelial cell polarity. J. Cell Biol., 217: 3853-3862. https://doi.org/10.1083/jcb.201803099

Gosens, I., Sessa, A., Letteboer, S.J, Belloni, V., Arends, M.L., Le, Bivic A, Cremers, F.P., Broccoli, V. and Roepman, R., 2007. FERM protein EPB41L5 is a novel member of the mammalian CRB-MPP5 polarity complex. Exp. Cell Res., 313: 3959-3970. https://doi.org/10.1016/j.yexcr.2007.08.025

Hashimoto, S., Mikami, S., Sugino, H., Yoshikawa, A., Hashimoto, A., Onodera, Y., Furukawa, S., Handa, H., Oikawa, T., Okada, Y., Oya, M. and Sabe, H., 2016. Lysophosphatidic acid activates Arf6 to promote the mesenchymal malignancy of renal cancer. Nat. Commun., 7: 10656. https://doi.org/10.1038/ncomms10656

Haugsten, E.M., Wiedlocha, A., Olsnes, S. and Wesche J., 2010. Roles of fibroblast growth factor receptors in carcinogenesis. Mol. Cancer Res., 8: 1439-1452. https://doi.org/10.1158/1541-7786.MCR-10-0168

Heinzle, C., Sutterluty, H., Grusch, M., Grasl-Kraupp, B., Berger, W. and Marian, B., 2011. Targeting fibroblast growth factor receptor dependent signaling for cancer therapy. Expert. Opin. Ther. Targets, 15: 829-846. https://doi.org/10.1517/14728222.2011.566217

Hirano, M., Hashimoto, S., Yonemura, S., Sabe, H. and Aizawa, S., 2008. EPB41L5 functions to post-transcriptionally regulate cadherin and integrin during epithelial-mesenchymal transition. J. Cell Biol., 182: 1217-1230. https://doi.org/10.1083/jcb.200712086

Li, B.B., Tang, X.G. and Liu, H.W., 2019. miR-184 regulates the proliferation and migration of rat renal carcinoma cells by inhibiting EPB41L5. Genom. appl. Biol., 38: 3312-3316.

Meng, Q.H., Xu, E., Hildebrandt, M.A., Liang, D., Lu, K., Ye, Y., Wagar, E.A. and Wu, X., 2014. Genetic variants in the fibroblast growth factor pathway as potential markers of ovarian cancer risk, therapeutic response, and clinical outcome. Clin. Chem., 60: 222-232. https://doi.org/10.1373/clinchem.2013.211490

Qin, A., Johnson, A., Ross, J.S., Miller, V.A., Ali, S.M., Schrock, A.B. and Gadgeel, S.M., 2019. Detection of known and novel FGFR fusions in non-small cell lung cancer by comprehensive genomic profiling. J. Thorac. Oncol., 14: 54-62. https://doi.org/10.1016/j.jtho.2018.09.014

Rhim, A.D., Mirek, E.T., Aiello, N.M., Maitra, A., Bailey, J.M., McAllister, F., Reichert, M., Beatty, G.L., Rustgi, A.K., Vonderheide, R.H., Leach, S.D. and Stanger, B.Z., 2012. EMT and dissemination precede pancreatic tumor formation. Cell, 148: 349-361. https://doi.org/10.1016/j.cell.2011.11.025

Sordella, R., Jiang, W., Chen, G.C., Curto, M. and Settleman, J., 2003. Modulation of Rho GTPase signaling regulates a switch between adipogenesis and myogenesis. Cell, 113: 147-158. https://doi.org/10.1016/S0092-8674(03)00271-X

Takakuwa, Y., Tchernia, G., Rossi, M., Benabadji, M. and Mohandas, N., 1986. Restoration of normal membrane stability to unstable protein 4.1-deficient erythrocyte membranes by incorporation of purified protein 4.1. J. clin. Invest., 78: 80-85. https://doi.org/10.1172/JCI112577

Tao, L., Yang, H.Y., Jiang, Y.T., He, X.Y., Hong, Q.H. and Chu, M.X., 2020. Canonical correlation analysis of body weight and adult traits of Yunshang black goat. Chin. Agric. Sci. Bull., 36: 108-112.

Tao, L., Yang, H.Y., Jiang, Y.T., Hong, Q.H. and Chu, M.X., 2020. Path analysis of the effect of body measurement traits on body weight of Yunshang black goat. J. Domest. Anim. Ecol., 41: 18-22.

Tepass, U., 2009. FERM proteins in animal morphog enesis. Curr. Opin. Genet. Dev., 19: 357-367. https://doi.org/10.1016/j.gde.2009.05.006

Turner, N. and Grose, R., 2010. Fibroblast growth factor signalling: From development to cancer. Nat. Rev. Cancer, 10: 116-129. https://doi.org/10.1038/nrc2780

Wang, J.J., Zhang, T., Chen, Q.M., Zhang, R.Q., Li, L., Cheng, S.F., Shen, W. and Lei, C.Z., 2020. Genomic signatures of selection associated with litter size trait in jining gray goat. Front. Genet., 11: 286. https://doi.org/10.3389/fgene.2020.00286

Zheng, H., Jiang, Y.H., Zhang, C.B., Gao, X.T., Zhai, Q.Y., Li, Y.Y., Cui, Y.Y., Xia, Q., Wei, Y.M. and Jiang, Q.Y., 2021. The effect of parity and temperature on lambing performance of Nubian goats. Heilongjiang Anim. Sci. Vet. Med., 8: 48-52.

Zhu, L., Wang, P., Hong, Q.H., Yang, H.Y., Zhao, X.L. and Lan, R., 2021. Association analysis of 3 SNPs polymorphisms on chromosome 28 of Yunshang black goat and litter size traits. China Anim. Husband. Vet. Med., 48: 1294-1301.

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Pakistan Journal of Zoology

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Pakistan J. Zool., Vol. 56, Iss. 6, pp. 2501-3000

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