Journal of Animal Science and Technology

Korean Society of Animal Sciences and Technology (한국축산학회)
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Lipogenesis Gene Expression Profiling in Longissimus dorsi on the Early and Late Fattening stage of Hanwoo

한우 비육 전·후기의 등심조직에 있어서 지방합성 유전자 발현

  • Published : 2006.06.30
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Abstract

Korean native cattle (Hanwoo) have a good capacity to produce heavily marbled meat of high value. The intramuscular fat in Hanwoo is known to be deposit from 12 months of age by degree of slightly visible and significantly developed in 28 months of age. Lipogenesis gene expression profiling in longissimus dorsi at early and late fattening stage will be helpful to understand the mechanism of intramuscular fat deposition in skeletal muscle. Therefore, we analysed the gene expression patterns of six genes related lipid metabolism (FABP4, GLUT4, LPL, ACC, ACL and SCD) between early and late fattening stage. The mRNA expression of FABP4 at late fattening stage (27 months old) was higher about 3.0 fold than at early fattening stage (12 months old) in each three individuals of Hanwoo. However, GLUT4 mRNA expression was not different at late fattening stage compared with at early fattening stage. On the other hand, The expression patterns of LPL, ACC, ACL and SCD genes related lipid metabolism were significantly over-expressed about 3.5 fold, 2.7 fold, 3.7 fold and 7.5 fold at late fattening stage, respectively. Thus, these results suggested that lipogenesis in skeletal muscle at late fattening stage is due to increasing uptake of fatty acid by FABP4 and lipogenesis gene expression such as LPL, ACC, ACL and SCD.

지방합성이 왕성하게 진행되는 비육후기의 근육내 지방합성에 있어서, 지방산 및 당의 이용경로 및 이에 따른 근육내 지방합성과정을 규명하기 위해서 지방산 및 당 운반 유전자인 FABP4, GLUT4와 근육내 지방대사 주요유전자인 ACL, ACC, LPL 및 SCD 유전자의 mRNA 발현양상을 분석하였다. 한우 비육전기 및 후기 각 3두를 공시하여 total RNA 추출 및 1st cDNA 합성하여 SYBR green을 이용하여 real-time PCR 분석을 각 유전자별로 3반복씩 수행하였다. FABP4 유전자는 비육전기에 비해 비육후기에 있어서, 3배 이상 유전자 발현이 증가함을 확인할 수 있었고, GLUT4 유전자는 비육전기 및 비육후기에서 큰 차이를 보이지 않았다. 또한 근육내 지방합성 주요유전자인 ACL, ACC, LPL 및 SCD 유전자의 발현량은 비육후기에서 ACL 유전자가 3.8배, ACC 유전자는 2.7배, LPL 유전자는 3.5배, 그리고 SCD 유전자는 7.5배 발현량이 증가하였다. 따라서 본 연구를 통하여 한우의 비육후기에서 근육내 지방합성은 FABP4에 의한 지방산 유입의 증가와 더불어 ACL 유전자에 의해서 지방산 합성의 중간대사물인 acetyl-CoA가 합성되고, 이 중간 대사물을 이용하여 ACC 및 SCD 유전자에 의해서 긴 사슬 지방산 합성이 왕성하게 일어남을 알 수 있었다.

Keywords

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