Genetic Conservation and Utilization of Indigenous Livestock in Northern Thailand (PDF)
(Sprache: Englisch)
In recent years livestock production in Thailand has switched from backyard systems to
industrialized husbandry. In parallel, exotic livestock was imported to improve
production performance and for economically important traits. Indigenous livestock...
industrialized husbandry. In parallel, exotic livestock was imported to improve
production performance and for economically important traits. Indigenous livestock...
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In recent years livestock production in Thailand has switched from backyard systems to
industrialized husbandry. In parallel, exotic livestock was imported to improve
production performance and for economically important traits. Indigenous livestock has
therefore gradually been used for crossbreeding and was finally replaced completely by
exotic commercial breeds. However, these breeding strategies oppose the concepts of
sustainability and resource management and will lead to the threatening risk of losing
genetic identity and diversity of indigenous breeds.
For that reason, the overall goals of this study are to gain genetic information at
the molecular level that is indispensable to conserving Thai pigs and cattle breeds as
well as to define their potential as genetic resources. In particular, this study is aimed at:
(1) to investigate the mtDNA composition and to determine the genetic diversity
of pigs indigenous to Northern Thailand,
(2) to assess the phylogeny of Thai indigenous pigs, to compare them with further
Asian and European pigs and to clarify their origin of domestication,
(3) to compare the genetic background of Thai indigenous pigs with commercial
pigs used for meat production in Thailand and with selected Chinese pig breeds (i.e.
Jiangquhai, Luchuan, Minzhu, Rongchang, Yujiang and Tibetan),
(4) to search for sequence polymorphisms within the bovine HSP90AB1, to record
physiological responses against heat stress and to describe putative associations
between them in three cattle breeds used in Thailand.
The complete mtDNA control region (1264-1324 bp depending on the individual)
was comparatively sequenced to determine the degree of shared haplotypes, the
population structure and the phylogenetic relationships within Thai pig populations. For
that, samples of 72 Thai native pigs and 11 Thai wild boars were collected in six regions
(i.e. Mae Hongson, Southern and Northern part of Chiang Mai, Chiang Rai, Nan and
Uttaradit provinces) of Northern Thailand. In total 36 nucleotide variations leading to the
formation of 24 different haplotypes were described (TNH01 to TNH02 and TWH01 to
TWH04). The phylogenetic tree was separated into two main clades: a European (E)
clade and an Asian (A) clade with further Asian subclades (AS1, AS2 and THG).
Twenty-three of the 24 mtDNA haplotypes were integrated into the Asian clade of the
phylogenetic tree and eight of them recapitulated another major cluster of haplotypes
(THG). One haplotype (TNH01) fit to the European clade of the phylogenetic tree.
Average pairwise distances of 0.0136 ± 0.0029 (between AS2 and THG), of
0.0109 ± 0.0023 (between AS2 and AS1) and of 0.0084 ± 0.0023 (between THG and
AS1) resulted in estimates for the time since divergence of 90,000 - 496,000 years
between mtDNA clade AS2 and clade THG, 72,000 - 397,000 years between clade AS2
and clade AS1, and 56,000 - 306,000 years between clade THG and clade AS1. The
data implies that THG and AS1 diverged from the AS2 clade, but also that AS1 is
evolutionarily older than THG. In addition, our present study suggested that Thai
native pigs are closely related with Thai wild boars, but are also distinctly separated
from them enough and can be traced back to the common Asian ancestor.
An additional analysis using 510 bp of the sequenced mtDNA incorporated the
THG haplotypes to clade MTSEA (mountainous and Southeast Asian distribution) to
form haplogroup MTSEA-THG. Recently, MTSEA was renamed in MC3. MC3
contains only signatures of pigs scattered across the Indo-Burma Biodiversity Hotspot
(IBBH), a region including Thailand to the Kra Isthmus. The assignment of the 15
porcine Thai haplotypes to cluster AS1, supports the hypothesis of a shared common
ancestors with the Chinese domestic pigs, but the formation of the separate MTSEATHG
clade is also most putatively an indication for a further independent domestication
event in Southeast Asia (SEA) in the past. All haplotypes of haplogroup MTSEA-THG
have revealed unique and previously unknown nucleotide signatures at positions 24
(nucleotide A) and at positions 183 (nucleotide C) that differentiate them from all other
porcine mtDNA haplotypes.
The genetic background and genetic diversity at the nuclear DNA level of the
Thai indigenous breeds was analyzed using 26 microsatellite markers. Thai indigenous
pig populations have a high genetic diversity being mirrored in relatively high scores for
the effective heterozygosity (He; 0.71) and the effective number of alleles (Ne; 3.71).
Furthermore, the genetic distances, the pairwise proportion of different alleles, the
neighbour-joining tree and the multidimensional analysis indicated a close genetic
relationship between the Thai indigenous and the selected Chinese pigs. Contrary to that
Thai pigs are distinctly different from European pigs. Nevertheless, a genetic
introgression traced back to European commercial breeds is evident in some of the Thai
native pigs. The genetic analyses clearly point out that Thai native pig populations are
unique genetic resources.
Thailand is a tropical country and lies in the hot and humid climatic zones of the
world. The environmental heat, resp. the heat stress, is most detrimental to cattle
production and welfare which can be visible, for example, a hindrance of feed
consumption, a decreased milk production and a limited reproduction performance.
Heat shock proteins act as molecular chaperones that have preferentially been
transcribed in response to severe perturbations of the cellular homeostasis, such as heat
stress. Thus, the traits respiration rate (RR), rectal temperature (RT), pack cell volume
(PCV), and the individual heat tolerance coefficient (HTC) were recorded as
physiological responses on heat stress (environmental temperatures) in Bos taurus
(crossbred Holstein Friesian; HF) and Bos indicus (Thainative cattle: White Lamphun;
WL and Mountain cattle; MT) animals. The 47 apparently healthy not lactating females
were randomly selected and kept at the experimental farm of the Chiang Mai University
in Thailand. RR and RT were measured in the morning (8:00 am) and in the afternoon
(2:00 pm), two weeks per month for four consecutive months (September to December)
to achieve 8 observations per animal. During the experimental time an averaged
surrounding temperature of 22 °C with 94% relative humidity was measured in the
morning. The records for the afternoon were 34°C and 68% relative humidity.
Polymorphisms of the heat shock protein 90-kDa beta gene (HSP90AB1) were
evaluated by comparative sequencing of animals representing Bos taurus and Bos
indicus. Nine SNPs were identified, i.e. three in exons 10 and 11, five in introns 8, 9,
10, 11, and one was located in the 3'UTR. The exon 11 SNP g.5082 C>T led to a missense
mutation (alanine to valine), the further SNPS proved to be silent. The calculated
genetic heterozygosity based on allele frequencies suggests a higher genetic diversity of
Thai native cattle (MT = 0.326 and WL = 0.307) compared to the Bos taurus animals
(HF = 0.071). During the period of extreme heat (in the afternoon) RR and RT were in
each of the three breeds elevated, whereas the PCV decreased. MT and WL were
superior in all physiological traits compared to HF. The association analysis using a
stepwise regression revealed that the T allele at SNP g.4338T>C within intron 9
improved the heat tolerance (p < 0.05) of the animals. Allele T was exclusively found in
WL animals and to 84% in MT. HF cattle revealed an allele frequency of only 18%. The
study indicates breed specific physiological responses to heat stress. Here,
polymorphisms within HSP90AB1 were not causative for the physiological responses,
however, the results propose that this gene is an attractive candidate for heat tolerance,
and should at least be used as a genetic marker to select appropriate breeds for hot
climates.
industrialized husbandry. In parallel, exotic livestock was imported to improve
production performance and for economically important traits. Indigenous livestock has
therefore gradually been used for crossbreeding and was finally replaced completely by
exotic commercial breeds. However, these breeding strategies oppose the concepts of
sustainability and resource management and will lead to the threatening risk of losing
genetic identity and diversity of indigenous breeds.
For that reason, the overall goals of this study are to gain genetic information at
the molecular level that is indispensable to conserving Thai pigs and cattle breeds as
well as to define their potential as genetic resources. In particular, this study is aimed at:
(1) to investigate the mtDNA composition and to determine the genetic diversity
of pigs indigenous to Northern Thailand,
(2) to assess the phylogeny of Thai indigenous pigs, to compare them with further
Asian and European pigs and to clarify their origin of domestication,
(3) to compare the genetic background of Thai indigenous pigs with commercial
pigs used for meat production in Thailand and with selected Chinese pig breeds (i.e.
Jiangquhai, Luchuan, Minzhu, Rongchang, Yujiang and Tibetan),
(4) to search for sequence polymorphisms within the bovine HSP90AB1, to record
physiological responses against heat stress and to describe putative associations
between them in three cattle breeds used in Thailand.
The complete mtDNA control region (1264-1324 bp depending on the individual)
was comparatively sequenced to determine the degree of shared haplotypes, the
population structure and the phylogenetic relationships within Thai pig populations. For
that, samples of 72 Thai native pigs and 11 Thai wild boars were collected in six regions
(i.e. Mae Hongson, Southern and Northern part of Chiang Mai, Chiang Rai, Nan and
Uttaradit provinces) of Northern Thailand. In total 36 nucleotide variations leading to the
formation of 24 different haplotypes were described (TNH01 to TNH02 and TWH01 to
TWH04). The phylogenetic tree was separated into two main clades: a European (E)
clade and an Asian (A) clade with further Asian subclades (AS1, AS2 and THG).
Twenty-three of the 24 mtDNA haplotypes were integrated into the Asian clade of the
phylogenetic tree and eight of them recapitulated another major cluster of haplotypes
(THG). One haplotype (TNH01) fit to the European clade of the phylogenetic tree.
Average pairwise distances of 0.0136 ± 0.0029 (between AS2 and THG), of
0.0109 ± 0.0023 (between AS2 and AS1) and of 0.0084 ± 0.0023 (between THG and
AS1) resulted in estimates for the time since divergence of 90,000 - 496,000 years
between mtDNA clade AS2 and clade THG, 72,000 - 397,000 years between clade AS2
and clade AS1, and 56,000 - 306,000 years between clade THG and clade AS1. The
data implies that THG and AS1 diverged from the AS2 clade, but also that AS1 is
evolutionarily older than THG. In addition, our present study suggested that Thai
native pigs are closely related with Thai wild boars, but are also distinctly separated
from them enough and can be traced back to the common Asian ancestor.
An additional analysis using 510 bp of the sequenced mtDNA incorporated the
THG haplotypes to clade MTSEA (mountainous and Southeast Asian distribution) to
form haplogroup MTSEA-THG. Recently, MTSEA was renamed in MC3. MC3
contains only signatures of pigs scattered across the Indo-Burma Biodiversity Hotspot
(IBBH), a region including Thailand to the Kra Isthmus. The assignment of the 15
porcine Thai haplotypes to cluster AS1, supports the hypothesis of a shared common
ancestors with the Chinese domestic pigs, but the formation of the separate MTSEATHG
clade is also most putatively an indication for a further independent domestication
event in Southeast Asia (SEA) in the past. All haplotypes of haplogroup MTSEA-THG
have revealed unique and previously unknown nucleotide signatures at positions 24
(nucleotide A) and at positions 183 (nucleotide C) that differentiate them from all other
porcine mtDNA haplotypes.
The genetic background and genetic diversity at the nuclear DNA level of the
Thai indigenous breeds was analyzed using 26 microsatellite markers. Thai indigenous
pig populations have a high genetic diversity being mirrored in relatively high scores for
the effective heterozygosity (He; 0.71) and the effective number of alleles (Ne; 3.71).
Furthermore, the genetic distances, the pairwise proportion of different alleles, the
neighbour-joining tree and the multidimensional analysis indicated a close genetic
relationship between the Thai indigenous and the selected Chinese pigs. Contrary to that
Thai pigs are distinctly different from European pigs. Nevertheless, a genetic
introgression traced back to European commercial breeds is evident in some of the Thai
native pigs. The genetic analyses clearly point out that Thai native pig populations are
unique genetic resources.
Thailand is a tropical country and lies in the hot and humid climatic zones of the
world. The environmental heat, resp. the heat stress, is most detrimental to cattle
production and welfare which can be visible, for example, a hindrance of feed
consumption, a decreased milk production and a limited reproduction performance.
Heat shock proteins act as molecular chaperones that have preferentially been
transcribed in response to severe perturbations of the cellular homeostasis, such as heat
stress. Thus, the traits respiration rate (RR), rectal temperature (RT), pack cell volume
(PCV), and the individual heat tolerance coefficient (HTC) were recorded as
physiological responses on heat stress (environmental temperatures) in Bos taurus
(crossbred Holstein Friesian; HF) and Bos indicus (Thainative cattle: White Lamphun;
WL and Mountain cattle; MT) animals. The 47 apparently healthy not lactating females
were randomly selected and kept at the experimental farm of the Chiang Mai University
in Thailand. RR and RT were measured in the morning (8:00 am) and in the afternoon
(2:00 pm), two weeks per month for four consecutive months (September to December)
to achieve 8 observations per animal. During the experimental time an averaged
surrounding temperature of 22 °C with 94% relative humidity was measured in the
morning. The records for the afternoon were 34°C and 68% relative humidity.
Polymorphisms of the heat shock protein 90-kDa beta gene (HSP90AB1) were
evaluated by comparative sequencing of animals representing Bos taurus and Bos
indicus. Nine SNPs were identified, i.e. three in exons 10 and 11, five in introns 8, 9,
10, 11, and one was located in the 3'UTR. The exon 11 SNP g.5082 C>T led to a missense
mutation (alanine to valine), the further SNPS proved to be silent. The calculated
genetic heterozygosity based on allele frequencies suggests a higher genetic diversity of
Thai native cattle (MT = 0.326 and WL = 0.307) compared to the Bos taurus animals
(HF = 0.071). During the period of extreme heat (in the afternoon) RR and RT were in
each of the three breeds elevated, whereas the PCV decreased. MT and WL were
superior in all physiological traits compared to HF. The association analysis using a
stepwise regression revealed that the T allele at SNP g.4338T>C within intron 9
improved the heat tolerance (p < 0.05) of the animals. Allele T was exclusively found in
WL animals and to 84% in MT. HF cattle revealed an allele frequency of only 18%. The
study indicates breed specific physiological responses to heat stress. Here,
polymorphisms within HSP90AB1 were not causative for the physiological responses,
however, the results propose that this gene is an attractive candidate for heat tolerance,
and should at least be used as a genetic marker to select appropriate breeds for hot
climates.
Bibliographische Angaben
- 2011, 166 Seiten, Englisch
- Verlag: Cuvillier Verlag
- ISBN-10: 3736938004
- ISBN-13: 9783736938007
- Erscheinungsdatum: 20.06.2011
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