利用功能分类基因芯片研究不同品种猪脂肪中特定基因的发育性变化

利用Oligo功能分类基因芯片检测了瘦肉型的长白猪和脂肪型的太湖猪在1、2、3、4和5月龄间背部皮下脂肪中脂肪沉积代谢和细胞生长调控相关基因的动态表达变化。差异表达分析结果显示1~5月龄的品种间分别有10、6、11、8和19个基因的表达差异倍数大于2倍, 且长白猪有25个基因在不同月龄间的表达差异达显著水平(P<0.05)。其中血管生成素样蛋白4 (ANGPTL4)、组织蛋白酶K (CTSK) 、异柠檬酸脱氢酶2(NADP+) (IDH2)、脂蛋白脂酶 (LPL)、苹果酸酶1 (ME1)、 硬酯酰辅酶A去饱和酶 (SCD)和解藕联蛋白2 (UCP2)这7个基因不仅在同月龄的品种间和品种内的不同月龄间差异表达, 主成分分析结果也显示其表达模式明显偏离其他基因, 提示受到了特殊的调控。聚类分析结果显示1~5月龄间长白猪中正调控脂肪酸代谢基因的表达量逐渐上调, 太湖猪中参与细胞生长调控基因的表达量平缓波动且变化幅度相对较小。另外, 5个差异表达基因的荧光定量RT-PCR验证结果均与芯片结果呈正相关趋势。结果成功筛选出了对猪胴体和肉质性状可能具有重要影响并值得深入研究的一些候选基因, 初步揭示了相关基因的表达变化规律, 为了解生长发育过程中脂肪酸合成与水解的动态平衡过程提供了基础数据。     

利用功能分类基因芯片研究不同品种猪脂肪中特定基因的发育性变化

利用Oligo功能分类基因芯片检测了瘦肉型的长白猪和脂肪型的太湖猪在1、2、3、4和5月龄间背部皮下脂肪中脂肪沉积代谢和细胞生长调控相关基因的动态表达变化。差异表达分析结果显示1~5月龄的品种间分别有10、6、11、8和19个基因的表达差异倍数大于2倍, 且长白猪有25个基因在不同月龄间的表达差异达显著水平(P<0.05)。其中血管生成素样蛋白4 (ANGPTL4)、组织蛋白酶K (CTSK) 、异柠檬酸脱氢酶2(NADP+) (IDH2)、脂蛋白脂酶 (LPL)、苹果酸酶1 (ME1)、 硬酯酰辅酶A去饱和酶 (SCD)和解藕联蛋白2 (UCP2)这7个基因不仅在同月龄的品种间和品种内的不同月龄间差异表达, 主成分分析结果也显示其表达模式明显偏离其他基因, 提示受到了特殊的调控。聚类分析结果显示1~5月龄间长白猪中正调控脂肪酸代谢基因的表达量逐渐上调, 太湖猪中参与细胞生长调控基因的表达量平缓波动且变化幅度相对较小。另外, 5个差异表达基因的荧光定量RT-PCR验证结果均与芯片结果呈正相关趋势。结果成功筛选出了对猪胴体和肉质性状可能具有重要影响并值得深入研究的一些候选基因, 初步揭示了相关基因的表达变化规律, 为了解生长发育过程中脂肪酸合成与水解的动态平衡过程提供了基础数据。     

长白猪和太湖猪不同生长阶段脂肪中肉质和胴体性状相关基因的表达谱分析

动物个体的皮下脂肪厚度（subcutaneous fat thickness,SFT）和肌内脂肪（intramuscular fat,IMF）含量取决于活体内脂肪酸合成与氧化竞争的动态平衡点．利用包含140个与猪脂肪沉积、代谢和肌肉生长密切相关基因的Oligo功能分类基因芯片检测了脂肪型的太湖猪和瘦肉型的长白猪在1,2,3,4和5月龄间背部皮下脂肪中这些基因的动态表达变化,发现长白猪有25个基因在月龄间的表达差异达显著水平（P〈0．05）,且包含23个基因的“参与脂肪或类固醇代谢的酶和调节蛋白”基因分组在品种间具有极显著意义（P〈0．01）．提示两猪种脂肪沉积能力的巨大表型差异可能与这些基因的差异表达规律密切相关．STEM聚类分析显示长白猪和太湖猪各有两个表达模式分别具有极显著（P〈0．01）和显著性意义（P〈0．05）,但太湖猪基因表达谱比较分散,占主导优势的表达模式没有长白猪明显．提示太湖猪脂肪细胞内参与相关代谢活动的基因间的调控关系较长白猪复杂．基于动态贝叶斯模型构建的基因调控网络从一定程度上反映了两猪种在脂肪沉积代谢相关生理生化活动方面存在的明显差异,可从中挖掘相关性状潜在的关键特征基因．此外,对5个差异表达基因的荧光定量RT-PCR验证显示两种实验方法结果的相关系数平均高达0．874±0．071．以上结果筛选出了对于猪脂肪相关性状可能具有重要影响并值得深入研究的一些基因,初步揭示了生长发育过程中脂肪细胞基因表达调控的分子互作机制．     

雌性藏猪不同生长发育阶段肌肉生长和脂肪沉积相关基因的表达模式

本研究利用包含140个与猪肌肉生长和脂肪沉积密切相关基因的Oligo功能分类基因芯片检测了藏猪在2、4、6和8月龄间背最长肌中这些基因的表达量变化,并在2月龄时与脂肪型的太湖猪和瘦肉型的长白猪进行比较.ANOVA分析结果表明:2-8月龄间藏猪分别有10和 7个基因的表达差异达极显著(P<0.01)和显著水平(P<0.05);2月龄时藏猪体重极显著低于长白猪(P<0.01)和显著低于太湖猪(P<0.05),而藏猪肌纤维面积却为最大,但品种间差异未达显著水平(P>0.05);2月龄时3个品种间分别有15和13个基因的表达差异达极显著 (P<0.01)和显著水平(P<0.05).STEM聚类分析结果表明:直线下降和上升是藏猪在2 -8月龄间最具代表性的基因表达模式(P<0.01).另外,5个差异表达基因的荧光定量RT -PC R验证结果与基因芯片结果的Person相关系数平均高达0.856±0.109.提示:藏猪在2-8月龄间骨骼肌生长发育强度较肌内脂肪合成沉积占优势,2月龄时藏猪脂肪酸合成相关基因的表达水平较其他两品种低,而脂肪酸β氧化和肌纤维生长相关基因的表达水平较高,与其在高原独特的自然生态环境和全放牧散养的饲喂方式下长期形成的品种特性相符 [动物学报 54(3):442-452,2008].     

猪脂肪组织中IGF2和IGFBP3基因表达的发育性变化及其品种差异

采用荧光定量PCR技术分析长白猪和太湖猪背部皮下脂肪组织中胰岛素样生长因子2和胰岛素样生长因子结合蛋白3基因在30、60、90、120和150日龄时表达水平的发育性变化。结果表明: (1)品种内日龄间比较, 长白猪IGF2 mRNA 在30日龄时的表达量极显著高于其他日龄(P<0.01), 之后逐渐下降, 至120日龄降到最低, 150日龄时又明显上升; 太湖猪IGF2 mRNA在30~60日龄的表达量较高, 90日龄降至最低, 120日龄迅速回升, 之后又有所下降。两品种IGFBP3 mRNA表达的发育性变化模式基本相同, 30日龄时表达量最高, 60日龄显著下降(P<0.05), 之后趋于平缓但略有波动。(2)品种间同日龄比较, 120日龄时太湖猪IGF2 mRNA的表达量极显著高于长白猪(P<0.01), 150日龄时太湖猪IGFBP3的表达量极显著低于长白猪(P<0.01), 其余日龄间两品种差异均不显著(P>0.05)。研究结果提示: 猪脂肪组织IGF2和IGFBP3基因表达存在明显的发育性变化和品种差异; IGF2基因表达水平的降低可能与脂肪细胞的增殖有关。     

2个猪品种的背最长肌组织中兰尼定受体(RYR1)基因表达的发育性变化

本研究采用实时荧光定量PCR方法检测了长白猪和梅山猪背最长肌组织中RYR1基因mRNA表达量在初生(0月龄)、1月龄、2月龄、3月龄、4月龄和5月龄间的变化及其与体重、肌纤维面积(CSA)和肌内脂肪含量(IMF)之间的相关性。结果表明:长白猪的体重、CSA在多数月龄均高于梅山猪,而梅山猪的IMF在多数月龄均高于长白猪。两品种RYR1基因表达量的发育性表达模式极为相似,均表现为波动起伏中逐渐上升的趋势。相同月龄时,梅山猪RYR1基因的表达量均高于长白猪。本文初步揭示了两猪种生长发育过程中RYR1基因表达的发育性变化模式和品种差异,为进一步研究RYR1基因对猪肉质性状的影响提供了基础数据。     

猪产仔数性状基因效应与有效基因数的研究

利用太湖猪（Ｐ１）、长白猪（Ｐ２）、杂交一代（Ｆ１）、杂交二代（Ｆ２）、杂交三代（Ｆ３）;和回交一代（Ｂ２）等６个世代产仔数的材料,分析了猪产仔性状的基因效应和基因数。结果表明上位效应不显著,猪产仔数性状符合加性－显性遗传模式,受一个有效基因控制。太湖猪产仔数性状基因加性值比长白猪高１．３９头,太湖猪高产仔数基因对长白猪等位基因呈显性,显性度为０．８１。     

猪产仔数性状基因效应与有效因数的研究

利用太湖猪（Ｐ１）、长白猪（Ｐ２）、杂交一代（Ｆ１）、杂交二代（Ｆ２）、杂交三代（Ｆ２）和回交一代（Ｂ２）等６个世代产仔数的材料,分析了猪产仔性状的基因效应和基因数,结果表明上位效应不显著,猪产仔数性状符合加性－显性遗传模式,受一个有效基因控制。太湖猪产仔数性状基因加性值比长白猪高１．３９头,太湖猪高产仔在因对长白猪等位基因呈显性,显性度为０．８１。     

五指山猪和长白猪背最长肌差异基因的筛选与注释

为了筛选五指山猪和长白猪背最长肌组织差异表达基因,本研究采用RNA-seq技术和生物信息学方法对6月龄、8月龄五指山猪和长白猪的背最长肌进行转录组测序分析,并对差异表达基因进行GO和KEGG Pathway显著性富集分析。通过与猪基因组比对分析后发现,在6月龄和8月龄五指山猪和长白猪均有约44 000 000条Clean reads能够比对到猪基因组上相关基因,每个文库均获得约18 200个表达基因,而转录本的数据为25 000个。在6月龄五指山猪与长白猪中共有30个基因差异表达,在8月龄五指山猪与长白猪中获得29个差异表达的基因。这些差异表达的基因主要富集在与糖酵解代谢、MAPK信号代谢通路和胰岛素信号通路等肌肉发育信号通路,通过筛选获得了与肌肉生长发育有关的候选基因,为探索五指山猪肌肉发育的分子机制提供了理论依据。     

猪UCP3基因部分编码区序列分析及其单核苷酸多态与胴体、肉质性状的遗传效应

以猪解耦联蛋白基因 3(UCP3)作为控制猪胴体与肉质性状主基因的候选基因。利用直接测序法对 4个品种猪骨骼肌中UCP3基因的部分编码区序列 (第 4外显子部分及第 5、6、7外显子全部片段 )进行比较分析 ,发现3个cSNP位点 ,其中ORF中第 84 2碱基的突变可导致相应编码氨基酸序列的改变 :甲硫氨酸→苏氨酸 ,选取此位点作为猪UCP3基因的多态位点。用PCR SSCP检测方法在 3个品种猪中进行该cSNP位点多态性片段的基因型分型 ,结果显示在 3个猪群中表现出 3种基因型 (AA、AB、BB) ,χ2 独立性检验结果表明 3种基因型在各品种间分布不一致 ,梅山猪同大白、长白猪分别比较差异极显著 (P <0 0 1) ;对大白×梅山资源家系F2 代 139头个体进行了该多态片段的基因型鉴定 ,并对其基因型与所检测个体相应的胴体、肉质性状采用GLM分析进行遗传效应研究 ,结果表明 :该基因对一些胴体、肉质性状有显著性影响 ,并且该基因以加性效应为主 (如 ,眼肌高度、背最长肌色值、系水力的加性效应都达显著水平 )。因此 ,推测UCP3基因可能是影响猪胴体及肉质性状的主效基因或与主效基因紧密连锁的标记基因 ,并且能够在分子标记辅助选择中用于对猪胴体、肉质性状的遗传改良及固定     

Expression profiling analysis for genes related to meat quality and carcass traits during postnatal development of backfat in two pig breeds

The competitive equilibrium of fatty acid biosynthesis and oxidation in vivo determines porcine sub-cutaneous fat thickness(SFT) and intramuscular fat(IMF) content.Obese and lean-type pig breeds show obvious differences in adipose deposition;however, the molecular mechanism underlying this phenotypic variation remains unclear.We used pathway-focused oligo microarray studies to examine the expression changes of 140 genes associated with meat quality and carcass traits in backfat at five growth stages(1―5 months) of Landrace(a leaner, Western breed) and Taihu pigs(a fatty, indigenous, Chinese breed).Variance analysis(ANOVA) revealed that differences in the expression of 25 genes in Landrace pigs were significant(FDR adjusted permutation, P<0.05) among 5 growth stages.Gene class test(GCT) indicated that a gene-group was very significant between 2 pig breeds across 5 growth stages(PErmineJ<0.01), which consisted of 23 genes encoding enzymes and regulatory proteins associ-ated with lipid and steroid metabolism.These findings suggest that the distinct differences in fat deposition ability between Landrace and Taihu pigs may closely correlate with the expression changes of these genes.Clustering analysis revealed a very high level of significance(FDR adjusted, P<0.01) for 2 gene expression patterns in Landrace pigs and a high level of significance(FDR adjusted, P<0.05) for 2 gene expression patterns in Taihu pigs.Also, expression patterns of genes were more diversified in Taihu pigs than those in Landrace pigs, which suggests that the regulatory mechanism of micro-effect polygenes in adipocytes may be more complex in Taihu pigs than in Landrace pigs.Based on a dy-namic Bayesian network(DBN) model, gene regulatory networks(GRNs) were reconstructed from time-series data for each pig breed.These two GRNs initially revealed the distinct differences in physiological and biochemical aspects of adipose metabolism between the two pig breeds;from these results, some potential key genes could be identified.Quantitative, real-time RT-PCR(QRT-PCR) was used to verify the microarray data for five modulated genes, and a good correlation between the two measures of expression was observed for both 2 pig breeds at different growth stages(R=0.874±0.071).These results highlight some possible candidate genes for porcine fat characteristics and provide some data on which to base further study of the molecular basis of adipose metabolism.     

Expression profiling analysis for genes related to meat quality and carcass traits during postnatal development of backfat in two pig breeds

The competitive equilibrium of fatty acid biosynthesis and oxidation in vivo determines porcine subcutaneous fat thickness (SFT) and intramuscular fat (IMF) content. Obese and lean-type pig breeds show obvious differences in adipose deposition; however, the molecular mechanism underlying this phenotypic variation remains unclear. We used pathway-focused oligo microarray studies to examine the expression changes of 140 genes associated with meat quality and carcass traits in backfat at five growth stages (1–5 months) of Landrace (a leaner, Western breed) and Taihu pigs (a fatty, indigenous, Chinese breed). Variance analysis (ANOVA) revealed that differences in the expression of 25 genes in Landrace pigs were significant (FDR adjusted permutation, P<0.05) among 5 growth stages. Gene class test (GCT) indicated that a gene-group was very significant between 2 pig breeds across 5 growth stages (P _ErmineJ<0.01), which consisted of 23 genes encoding enzymes and regulatory proteins associated with lipid and steroid metabolism. These findings suggest that the distinct differences in fat deposition ability between Landrace and Taihu pigs may closely correlate with the expression changes of these genes. Clustering analysis revealed a very high level of significance (FDR adjusted, P<0.01) for 2 gene expression patterns in Landrace pigs and a high level of significance (FDR adjusted, P<0.05) for 2 gene expression patterns in Taihu pigs. Also, expression patterns of genes were more diversified in Taihu pigs than those in Landrace pigs, which suggests that the regulatory mechanism of micro-effect polygenes in adipocytes may be more complex in Taihu pigs than in Landrace pigs. Based on a dynamic Bayesian network (DBN) model, gene regulatory networks (GRNs) were reconstructed from time-series data for each pig breed. These two GRNs initially revealed the distinct differences in physiological and biochemical aspects of adipose metabolism between the two pig breeds; from these results, some potential key genes could be identified. Quantitative, real-time RT-PCR (QRT-PCR) was used to verify the microarray data for five modulated genes, and a good correlation between the two measures of expression was observed for both 2 pig breeds at different growth stages (R=0.874±0.071). These results highlight some possible candidate genes for porcine fat characteristics and provide some data on which to base further study of the molecular basis of adipose metabolism.     

Molecular characterization of the BTG2 and BTG3 genes in fetal muscle development of pigs

BTG2 and BTG3 are two members of the B-cell translocation gene family with anti-proliferative properties. BTG1 gene in this gene family has been reported to play a key role in muscle growth. In this study, we identified and characterized the porcine BTG2 and BTG3 genes, mapped the two genes to porcine chromosomes, and analyzed their expression differences in the longissimus dorci muscle of 33 dpc (day postconception), 65 dpc and 90 dpc in the lean Landrace and fatty Chinese Tongcheng pig breeds. Expression changes in differentiated C2C12 cells were also investigated with myogenin as internal control. The results showed that the porcine BTG2 and BTG3 genes were mapped on SSC9q21-25 and SSC13q47, respectively. BTG2 gene expressed at high levels in skeletal muscle and heart in both Tongcheng and Landrace pigs whereas BTG3 gene expressed at lower levels in skeletal muscle and heart than in other tissues. Furthermore, BTG3 expressed at higher levels in skeletal muscle of Tonghceng compared with Landrace pig. The expression of BTG2 and BTG3 was significantly different in skeletal muscle among different developmental stages and between the two breeds. Expression analysis in murine myoblast cells showed that both genes were induced in differentiated C2C12 cells, suggesting a role of them in myogenic differentiation. Our study indicated that BTG2 and BTG3, especially BTG3 gene, may be important genes for skeletal muscle growth.