Keywords:

Genetic diversity

Landscape genetics

Native breeds

Genetic resources.

Exploring the genetic of three Hairless Pig breed populations in Mexico

Explorando la genética de tres poblaciones de la raza Cerdo Pelón en México

Explorando a genética de três populações da raça Porco Pelado no México

Gilberto Lemus Avalos

Javier Germán Rodríguez Carpena

William Orlando Burgos Paz

Clemente Lemus Flores

Carlos Alfredo Carmona Gasca

Rev. Fac. Agron. (LUZ). 2024, 41(3): e244122

ISSN 2477-9407

DOI: https://doi.org/10.47280/RevFacAgron(LUZ).v41.n3.02

Animal production

Associate editor: Dra. Rosa Razz

University of Zulia, Faculty of Agronomy

Bolivarian Republic of Venezuela

Doctorado en Ciencias Biológico Agropecuarias,

Universidad Autónoma de Nayarit. Doctorado en Ciencias

Biológico Agropecuarias en el Área de Ciencias Zootécnicas

y Veterinarias. Universidad Autónoma de Nayarit, Mexico.

Centro Nayarita de Innovación y Transferencia de la

Tecnología A.C. Tepic, Nayarit-México.

Corporación Colombiana de Investigación Agropecuaria-

AGROSAVIA. Centro de Investigación Turipaná, km 14 vía

Montería Cereté, Córdoba, Colombia.

Universidad Autónoma de Nayarit. Unidad Académica de

Medicina Veterinaria y Zootecnia. Compostela, Nayarit-

México.

Received: 17-05-2024

Accepted: 15-06-2024

Published: 01-07-2024

Abstact

The objective of this research was to carry out a molecular

genetic characterization of three Hairless Pig (HP) breed populations

located in México in the states of Nayarit, Oaxaca and Yucatán

to identify variations, selection eects and population genetic

relationships. From blood samples, a total of 163 animals from

three populations of HP were successfully genotyped. Genotyped

SNP data was employed to compute genetic diversity, population

structure and landscape genetic analysis. The parameters of

minor allele frequency (MAF), observed heterozygosity (Ho) and

Wright’s xation index (FIS) pointed out that the population of

Nayarit is the one with the greatest genetic diversity (MAF: 0.362,

Ho: 0.336, FIS: 0.061). Principal Component Analysis (PCA) and a

Neighbor-joining phylogenetic tree analysis showed diversication

among the three HP populations and pointed out a closer genetic

relationship between the HP populations and the Iberian pig breed.

The Admixture analysis showed as well common ancestry shared

from commercial and Iberian breeds in the HP populations in

dierent gradients. For the analysis of the relationships between

geographic and genetic distances, Mantel test was computed and the

results described a distribution pattern of the geographical locations

along the genetic distances similar to the clustering pattern of the

PCA and Neighbor-joining phylogenetic tree analysis. The results

obtained manage to present the HP poor conservation state and the

need to stablish a genetic conservation program meaning an eort

to prevent the loss of a signicant cultural, natural and genetic

resource.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Rev. Fac. Agron. (LUZ). 2024, 41(3): e244122 July-September. ISSN 2477-9407.

2-6 |

Resumen

El objetivo de esta investigación fue realizar una caracterización

genética molecular de tres poblaciones de Cerdo Pelón (CP)

ubicadas en México en los estados de Nayarit, Oaxaca y Yucatán

para identicar variaciones, efectos de selección y relaciones

genéticas poblacionales. Se genotiparon con éxito un total de 163

animales de tres poblaciones de CP. Se emplearon datos de los

SNP genotipados para calcular la diversidad genética, la estructura

de la población y el análisis genético-espacial. Los parámetros de

frecuencia de alelo menor (MAF), heterocigosidad observada (Ho)

y el índice de jación de Wright (FIS) señalaron que la población

de Nayarit es la de mayor diversidad genética (MAF: 0.362, Ho:

0.336, FIS: 0.061). El Análisis de Componentes Principales (ACP)

y el análisis logenético mostraron una diversicación entre las tres

poblaciones de CP y señalaron una relación genética estrecha entre las

poblaciones de CP y la raza de cerdo ibérico. El análisis de Admixture

mostró también una ascendencia compartida de razas comerciales e

ibéricas en las poblaciones de CP. En el análisis genético-espacial los

resultados describieron un patrón de distribución de las ubicaciones

geográcas en relación con las distancias genéticas similar al patrón

de agrupamiento del ACP y del análisis del árbol logenético. Los

resultados obtenidos logran presentar el mal estado de conservación

del CP y la necesidad de establecer un programa de conservación

genética que signique un esfuerzo para evitar la pérdida de un

importante recurso cultural, natural y genético.

Palabras clave: diversidad genética, genética del paisaje, razas

nativas, recursos genéticos.

Resumo

O objetivo desta pesquisa foi realizar uma caracterização genética

molecular de três populações da raça Porco Pelón (PP) localizadas

no México nos estados de Nayarit, Oaxaca e Yucatán para identicar

variações, efeitos de seleção e relações genéticas populacionais. Um

total de 163 animais de três populações de PC foram genotipados

com sucesso a partir de amostras de sangue. Dados SNP genotipados

foram utilizados para calcular a diversidade genética, estrutura

populacional e análise genética da paisagem. Os parâmetros de

diversidade genética mostraram diferentes graus de diversidade entre

as três populações de PP e indicam que a população Nayarit é a que

apresenta maior diversidade genética. A Análise de Componentes

Principais (ACP) e a análise logenético de Neighbor-joining

mostraram diversicação entre as três populações de PP. A análise

de mistura mostrou uma ancestralidade comum compartilhada entre

raças comerciais e ibéricas (grupos externos) para populações de PP

em diferentes gradientes. Para analisar as relações entre distâncias

geográcas e genéticas, foi realizado o teste de Mantel e os resultados

descreveram um padrão de distribuição de localizações geográcas

em relação às distâncias genéticas semelhante ao observado no

padrão de agrupamento ACP e na análise logenético de Neighbour-

joining. Os resultados obtidos conseguem apresentar o mau estado de

conservação do PP e a necessidade de estabelecer um programa de

conservação genética que signique um esforço para evitar a perda

de um importante recurso cultural, natural e genético.

Palavras-chave: diversidade genética, genética da paisagem, raças

nativas, recursos genéticos.

Introduction

The introduction and presence of the pig in the country date

back 500 years ago and there are currently local genotypes whose

populations are in critical and risky conservation states, as is the case

of the Hairless Pig breed (DAD- IS, 2020; Sierra et al., 2016). The

Hairless Pig breed (HP) can be found in the tropical areas of Mexico

and its coasts, both the Gulf and the Pacic and center of the country as

well, adapted to dierent climates and altitudes in dierent production

systems (Lemus-Flores et al., 2001), the latter inuencing its genetic

composition and therefore its relevance in knowing them. Its physical

and morphological characteristics include visible “Iberian type”

features such as its grayish black color, rectilinear head, ears that fall

over the eyes, and the absence of hair (DAD-IS, 2020; Lemus-Flores et

al., 2020). For decades, the HP breed has had relevance in the survival

economy of the Mayan people and for this reason it is considered a

notable zoogenetic resource as it has great rusticity and the ability

to take advantage of foods with low nutritional content eectively,

in addition to being part in its traditional gastronomy (Hernández et

al., 2020; Rosado-Aguilar et al., 2022). The HP breed in Mexico has

been displaced from traditional production systems, thus decreasing

its populations due to the introduction of select breeds (Sierra et al.,

2005). At present, there is no formal record of an estimated number

of individuals along the country and in the ocial information

of this organism there is no phenotypic, productive or molecular

characterization data (DAD-IS, 2020). Despite the above, currently

there are eorts to rescue it since the demand for the consumption of

its products has increased, especially in the so-called gourmet market

(Hernández et al., 2020). By implementing current methodologies, it

is possible to determine the origin, genetic diversity, ancestry of the

HP breed and thereby implement strategies to know its current identity

and its genetic dierences with respect to other breeds to establish a

racial guarantee for both the breed and its products (Govindarajan

et al., 2012; Kawęcka et al., 2016). This research allowed, through

studies of SNPs in dierent populations of HP breed, to carry out a

study of genetic diversity and population structure that will allow us

to have a historical basis for future actions of genetic assessments in

support of rescue and conservation programs.

Material and methods

Sample collection, genotyping and quality control

This study was carried out in three populations of Hairless Pig

breed (HP) dened according to the characteristics described in the

study by Lemus-Flores et al. (2020) (absence of hair, black skin,

without spots, black hoof and straight snout) located in Mexico: the

northwest Pacic coast (Nayarit; 8 females and 2 males from the

Faculty of Veterinary Medicine and Zootechnics of the Autonomous

University from Nayarit, Compostela, semi-technied production

system), the southwest Pacic coast (Oaxaca; 8 females and 2 males

from the locality of San Francisco Ixhuatán, rustic production system)

and southeast Atlantic coast (Yucatán; 117 females and 26 males from

the Mexican Association of Iberian Origin Pig Breeders of Yucatán,

Tizimín, semi-technied production system) (gure 1). Unrelated

individuals were selected for this study.

Blood samples were taken from the jugular vein and collected in

Vacutainer EDTA K2 tubes (Becton Dickinson, Franklin Lakes, NJ,

USA) following the recommendations of the Ocial Standards NOM-

051-ZOO-1995 on the humane treatment of animals, and NOM-062-

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Lemus et al. Rev. Fac. Agron. (LUZ). 2024 41(3): e244122

3-6 |

ZOO-1999 on the technical specications for the production, care

and processing. Later, a blood sample from each tube was collected

individually in blood cards (Neogen, Nebraska, USA) and were

shipped to Neogen (Neogen, Nebraska, USA) for genotyping using

the Porcine GGP 50K microarray chip (Neogen, Nebraska, USA)

was used for genotype analysis. A total of 163 animals from three

populations of HP breed were successfully genotyped and a total of

46,145 autosomal SNPs, out of the 50698 SNPs. The quality control

of data obtained from the analyzes was carried out using the PLINK

v1.9 software (Chang

et al., 2015) where SNPs with polymorphisms

with a value > 0.90 were included and considering the MAF (minor

allele frequency) to a value < 0.01 were excluded.

Figure 1. Geographic locations of the three populations of Hairless

Pig described in the present study. NAY, Faculty of

Veterinary Medicine and Zootechnics of the Autonomous

University of Nayarit, Compostela, Nayarit (21°13’49”N

104°52’56”W); OAX, San Francisco Ixhuatán, Oaxaca

(16°20’57”N 94°28’57”W); YUC, Tizimín, Yucatán

(21°08’43”N 88°08’58”W).

Genetic diversity indices

The genetic diversity analysis was evaluated considering the

parameters of minor allele frequency (MAF), observed heterozygosity

(Ho), expected heterozygosity (He) and the xation index of

individuals within the populations (Fis) with the PLINK v1 software.

1.9 (Chang

et al., 2015).

Genetic structure and ancestry

Principal Component Analysis (PCA) and the construction of the

graphs were designed using the R software (R Core Team, 2021) to

establish sample clustering projection onto the axis using the three HP

breed populations (Nayarit, Oaxaca and Yucatán). In addition, publicy

SNP databases from Iberian, Duroc and Large-White breeds (Burgos-

Paz et al., 2013; Yang et al., 2017) were considered for comparisons.

Also, a Neighbor-joining phylogenetic tree was built with the

DarWin software (Perrier and Jacquemoud-Collet, 2006) based on

data on the genetic IBS (identity by state) distances between the

studied populations. A bayesian clustering of individuals was also

estimated using Admixture 1.3 (Alexander et al., 2009). Herein, the

K=1 to K=6 genetic groups (clusters) were tested and cross validation

error was used to select the most likely K according to the author.

Relationships between geographic and genetic distances

To determine the relationship between the geographic and genetic

distances of the HP breed populations, the Mantel test was performed

employing the GenAlEx 6.5 software (Peakall and Smouse, 2012)

using the site coordinates of the populations and the genetic IBS

distance matrix generated using PLINK v1 software 1.9 (Chang

et al.,

2015).

Results and discussion

Genetic diversity

The highest values of Minor Allele Frequency (MAF) were

observed for HP populations from Nayarit and Oaxaca, while that the

lowest were presented by the population of Yucatán. The values of

expected heterozygosity (He) were the same for the three populations,

while those of observed heterozygosity (Ho) were higher in the

Nayarit and Yucatán populations and lower in the Oaxaca population.

The highest values for the Inbreeding Coecient (FIS) were shown

by Oaxaca population, while in contrast, the lowest were presented

by the Yucatán and Nayarit populations. Similar diversity values

were registered in Muñoz et al. (2019) and Bordonaro et al. (2023) in

European local pig breeds where the average Ho, and He values were

from 0.270 to 0.297 and 0.275 to 0.303 respectively. The above seems

to indicate that the Nayarit population is the one with the greatest

genetic diversity, since it presents higher levels of He and Ho, followed

by the Yucatán and Oaxaca populations, presumably due to the lack of

adequate management of its crossing with other commercial breeds

(Meuwissen et al., 2020; DeWoody et al., 2021). The high FIS values

along with the low heterocigocity values (He, Ho) in the Oaxaca

population, suggested a considerable degree of inbreeding, since FIS

measures how much excess or reduction in heterozygosity is present

between observed and expected heterozygosities in a population (Li

et al., 2004). The above may be caused by the small number of the

population, the rustic production system from which they come and

the issues that it implies like poor breeding control (Šalamon et al.,

2019, Zhong et al., 2023).

Table1. Genetic diversity parameters of the three populations of

Hairless Pig described in the present study.

Population N MAF Ho He FIS

Nayarit

10 0.362 0.336 0.358 0.061

Oaxaca

10 0.312 0.302 0.358 0.160

Yucatán

143 0.263 0.332 0.358 0.072

N: Sample size, MAF: minor allele frequency, Ho: observed heterozygosity,

He: expected heterozygosity, FIS: Wright’s xation index, for each analyzed

population.

Genetic structure and ancestry

The grouping pattern observed in the PCA (gure 2) showed

three separated clusters for the HP breed populations and another

two individual clusters for the commercial breeds (Duroc and Large-

White breeds) except for the Iberian breed, which overlapped with the

Oaxaca HP breed population.

Also, a Neighbor-joining phylogenetic tree (gure 3) showed a

close relationship for the Yucatán and Oaxaca HP breed populations

are closer to the Iberian pig.

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Rev. Fac. Agron. (LUZ). 2024, 41(3): e244122 July-September. ISSN 2477-9407.

4-6 |

Figure 2. Principal Component Analysis employing genetic

distances and commercial pig breeds data. NAY:

Nayarit Hairless Pig breed population, OAX: Oaxaca

Hairless Pig breed population, YUC: Yucatán Hairless

Pig breed population, DUR: Duroc breed pig population,

LW: Large-White pig breed population, ESIB: Iberian pig

breed population.

This suggests a closer relationship between the Iberian breed with

the population of Nayarit compared to commercial breeds (Large-

White and Duroc breeds). The latter results along with the PCA

data analysis, shows a similar distribution pattern in the HP breed

populations. The dierent distribution of the genetic relationships

among the commercial breeds and the HP breed populations observed

in a dierent gradient, denote their genetic diversity possibly due

to the highly variable feeding and breeding practices that can be

found in native breed populations (Monteiro et al., 2019), as shown

in Šalamon et al. (2019) and Zorc et al. (2022) where the genetic

diversity of Croatian, Serbian and Eslovenian local pig breeds results

heterogeneous.

According to the results of the Admixture analysis (gure 4)

ancestry by the commercial breeds can be observed in the three HP breed

populations. We evaluated dierent K values with the mixed ancestry

model (K = 1 to 6) and the one with lowest CV value was chosen.

Greater ancestry was shown especially in the Nayarit population,

in contrast with the Yucatán population. It can be observed that the

patterns in the HP breed populations exhibit historical inuence of the

Iberian pig breed than to the other commercial breeds data (Duroc and

Large-White), especially the Oaxaca HP breed population, agreeing

with the above PCA and Neighbor-joining phylogenetic tree analysis

results, the latter, in accordance with Lemus et al. (2023), where they

founded closer genetic relationships between Iberian breeds and the

HP breed.

To determine the relation between geographical and genetic

distances of the HP breed populations, Mantel tests were performed

in GenAlEx 6.5 software (Peakall and Smouse, 2012) employing

the populations site coordinates and IBS (Identity by state) genetic

distance matrix (gure 5). The coecient of determination (r

)

was 0.63, suggesting a positive correlation between genetic and

geographical distances.

Figure 3. Neighbor-joining phylogenetic tree in root like pattern

employing IBS analysis data. NAY: Nayarit Hairless

Pig breed population, OAX: Oaxaca Hairless Pig breed

population, YUC: Yucatán Hairless Pig breed population,

DUR: Duroc breed pig population, LW: Large-White breed

pig population, ESIB: Iberian pig population.

Figure 4. The proportion of mixed ancestry in the populations

analyzed was evaluated by ADMIXTURE 1.3

(Alexander et al., 2009) with a K=3 value. We evaluated

dierent K values with the mixed ancestry model (K =

1 to 6). NAY: Nayarit Hairless Pig breed population, OAX:

Oaxaca Hairless Pig breed population, YUC: Yucatán

Hairless Pig breed population, DUR: Duroc breed pig

population, LW: Large-White breed pig population, ESIB:

Iberian pig population.

Throught the PCA, Neighbor-joining phylogenetic tree analysis

and Mantel test results, a pattern can be described in the relationship

between genetic dierentiation and geographical distances among the

three HP breed populations.

This scientic publication in digital format is a continuation of the Printed Review: Legal Deposit pp 196802ZU42, ISSN 0378-7818.

Lemus et al. Rev. Fac. Agron. (LUZ). 2024 41(3): e244122

5-6 |

Figure 5. Mantel test results. A distribution pattern can

be observed according to genetic distances and

geographical distances between populations.

The pattern showed greater diversity and dierentiation as the

spatial distribution of the three HP breed populations analyzed were

further from the southeast of the country (Yucatán) and its southwest

and northwest coasts (Oaxaca and Nayarit) (gure 1), drawing a gene

ow presumably carried out by anthropogenic factors, the latter,

possibly due to the original and rst introduction points of European

pig breeds in the colonization events of America during the 15

and

centuries carried out by the Spanish Empire (Hancock, 2022)

and clearly distinguishing three distinct groups, as it is analyzed

in Cesconeto et al. (2017) and Pimentel et al. (2023), where it is

established a positive correlation between geographical and genetic

distances in animals involved in anthropogenic activities (pigs

and horses respectively) clearly dierentiating them into dierent

regional groups.

The clear genetic diversity of HP populations throughout their

geographical distribution and how in dierent locations their genetic

structure continues to be dierent, indicates that even belonging

to the same race, the populations present great diversity between

them indicating that despite their state of conservation they present

levels of introgression by commercial breeds demonstrating a poor

conservation state and the need to stablish a genetic conservation

program.

Conclusions

The results obtained indicate that the three HP breed populations

analyzed in the present research are dierent from each other and the

genetic diversity analysis results suggest that they are closely related

to the Iberian breed, genetically distant from the commercial breeds

and, at the same time, share ancestry in dierent degrees with them.

The above seems to indicate that the genetics of the HP breed are

dierent according to its distribution throughout the country and their

heterogeneous production systems.

The latter unveils their poor conservation state and the need to

stablish a genetic conservation program, meaning an eort to prevent

the loss of a signicant cultural, natural and genetic resource.

Have a more detailed description of the current state of these

populations, manage to present a clearer perspective of the future

necessary actions that must be taken for their adequate conservation as

local breeds and, as far as possible, establish a genetic reserve program.

Acknowledgments

This study was supported and funded by the Secretary for

Research, Innovation, and Higher Education, Mérida, Yucatán,

Mexico. William Orlando Burgos Paz thank to Corporación

Colombiana de Investigación Agropecuaria – AGROSAVIA for the

support in data analysis (project ID 1002471).

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