Gene expression profiles of adipose tissue of high-fat diet-induced obese rats by cDNA microarrays

To better understand the molecular basis of dietary obesity, we examined adipose tissue genes differentially expressed in a well-characterized rat model of high-fat diet (HFD)-induced obesity using cDNA microarrays. Male Sprague–Dawley rats were fed either the HFD or the normal diet. Seven weeks later, the weights of obese models (362.92 ± 39.65 g) were significantly higher than those of normal control rats (315.22 ± 42.30 g, P < 0.01) and the wet weights of adipose tissue of rats fed with HFD (9.29 ± 5.14 g) were significantly higher than those of normal control rats (4.09 ± 2.69 g, P < 0.01), which confirmed the successful preparation of obese models. cDNA microarrays containing 9 216 genes/Ests were used to investigate gene expression of adipose tissue. Autoradiographic analysis showed that 532, 154, and 22 genes were differently expressed over 2-, 3-, and 5-fold, respectively. The analysis of gene expression profiles indicated that 276 genes were up-regulated and 432 genes were down-regulated in response to HFD-induced obesity. Different clusters of genes associated with lipid metabolism, extracellular matrix, signal transduction, cytoskeleton, cell apoptosis, etc., such as VLCS-H2, DGAT, ACADVL, PHYH, SCD, ACACA, ACS, MMP-2, MMP-15, CD38, CAMK2D, CACNA1F, CAPZA2, TMOD3, ARPC2, KNS2, TPM1, MAPK8, GADD45B, DAXX, TOK-1, PRKACA, STAT6, were concerned.     

cDNA芯片研发及其在肥胖患者脂肪基因差异表达研究中的应用

为了加快基因功能的研究,利用已有的来源于不同组织的cDNA克隆,并通过交换和购买补充了低丰度和染色体覆盖不完全的部分cDNA,研制开发出具有相当代表性、覆盖较完全的高密度cDNA表达型基因芯片,每张芯片上含有384个质控DNA和12 630个cDNA探针,其中包括12 508个Unigene和122个表达序列标签(EST).利用这些芯片,对肥胖患者及正常人内脏脂肪组织基因表达谱进行了初步研究,并发现在肥胖患者内脏脂肪组织差异表达的基因,其中上调的有与凋亡相关的基因、与免疫有关的基因以及与能量代谢有关的基因等,而下调的主要是与脂肪酸及胆固醇合成有关的基因,对这些基因进一步的功能研究将为阐明肥胖发生机制奠定基础.     

Chemokine Expression in Inflamed Adipose Tissue Is Mainly Mediated by NF-κB

Immune cell infiltration of expanding adipose tissue during obesity and its role in insulin resistance has been described and involves chemokines. However, studies so far have focused on a single chemokine or its receptor (especially CCL2 and CCL5) whereas redundant functions of chemokines have been described. The objective of this work was to explore the expression of chemokines in inflamed adipose tissue in obesity. Human and mouse adipocytes were analyzed for expression of chemokines in response to inflammatory signal (TNF-α) using microarrays and gene set enrichment analysis. Gene expression was verified by qRT-PCR. Chemokine protein was determined in culture medium with ELISA. Chemokine expression was investigated in human subcutaneous adipose tissue biopsies and mechanism of chemokine expression was investigated using chemical inhibitors and cellular and animal transgenic models. Chemokine encoding genes were the most responsive genes in TNF-α treated human and mouse adipocytes. mRNA and protein of 34 chemokine genes were induced in a dose-dependent manner in the culture system. Furthermore, expression of those chemokines was elevated in human obese adipose tissue. Finally, chemokine expression was reduced by NF-κB inactivation and elevated by NF-κB activation. Our data indicate that besides CCL2 and CCL5, numerous other chemokines such as CCL19 are expressed by adipocytes under obesity-associated chronic inflammation. Their expression is regulated predominantly by NF-κB. Those chemokines could be involved in the initiation of infiltration of leukocytes into obese adipose tissue.     

Using gene expression to predict differences in the secretome of human omental vs. subcutaneous adipose tissue

The objective of this study was to characterize differences in the secretome of human omental compared with subcutaneous adipose tissue using global gene expression profiling. Gene expression was measured using Affymetrix microarrays (Affymetrix, Santa Clara, CA) in subcutaneous and omental adipose tissue in two independent experiments (n = 5 and n = 3 independent subjects; n = 16 arrays in total, 2 for each subject). Predictive bioinformatic algorithms were employed to identify secreted proteins. Microarray analysis identified 22 gene probe sets whose expression was significantly different with a fold change (FC) greater than 5 in expression in both experiments between omental and subcutaneous adipose tissue. Using bioinformatic predictive programs 11 of these 22 probe sets potentially coded for secreted proteins. Pathway network analysis of the secreted proteins showed that three of the proteins are part of a common pathway network. These proteins gremlin 1 (GREM1), pleiotrophin (PTN), and secretory leukocyte peptidase inhibitor (SLPI) are expressed respectively 43×, 23×, and 5× in omental adipose tissue relative to subcutaneous adipose tissue as determined by real-time PCR. The presence of GREM1, PTN, and SLPI protein in human adipose tissue was confirmed by western blotting. All three proteins are expressed in the human Simpson-Golabi-Behmel syndrome (SGBS) preadipocyte cell line. The expression of GREM1, PTN, and SLPI changed with the differentiation of the preadipocytes into mature adipocytes. Gene expression coupled with predictive bioinformatic algorithms have identified several genes coding for secreted proteins which are expressed differently in omental adipose tissue compared to subcutaneous adipose tissue proving a valid alternative approach to help further define the adipocyte secretome.     

Achieving antisense inhibition by oligodeoxynucleotides containing N(7)-modified 2'-deoxyguanosine using tumor necrosis factor receptor type 1.

Antisense oligodeoxynucleotides (ODNs) are being explored as therapeutic agents for the treatment of many disorders including viral infections, cancers, and inflammatory disorders. In addition, antisense technology can be of great benefit to those attempting to assign function to the multitude of new genes being uncovered in the genomics initiative. However, the demonstration that the gene-regulating effects produced by antisense-designed ODNs are attributable to an antisense mechanism of action requires carefully designed experimentation. Critical to the assignment of an antisense mechanism of action is the availability of nuclease-stable ODNs, inside cells, that have a high binding affinity with the target mRNA and modulate gene functions in a sequence-dependent manner. To help us achieve a goal of sequence-specific antisense activity we designed antisense ODNs containing C(5)-propyne-modified 2'-deoxyuracil and N(7)-propyne-modified 7-deaza-2'-deoxyguanosine bases and partially modified (phosphorothioate) internucleoside linkages. These modified ODNs were found to have enhanced binding affinity to their target mRNA sequences as well as reduced sequence-independent side effects. We used these ODNs to specifically inhibit p55 tumor necrosis factor receptor type 1 expression and tumor necrosis factor alpha-mediated functions in culture assays.     

Atelocollagen-based gene transfer in cells allows high-throughput screening of gene functions.

We have previously demonstrated that Atelocollagen, used clinically for wound healing, is a reliable safe carrier for gene delivery. To obtain phenotypic changes by gene expression of cDNA, we developed an efficient technique for high-throughput gene transfer and expression screening in mammalian cells in microarrays by precoating a microplate with an Atelocollagen complexed with cDNA to which cells are then seeded. The complexes with a nanoparticle form were efficiently transduced into cells without use of any additional transfection reagent, and they allowed for long-term gene expression without apparent chromosomal integration. The complex spotted onto the well of a microplate was stable for a long period and allowed the cells to transduce and express reporter genes in a dose-dependent manner. We also showed that the present method using Atelocollagen-based gene transfer is applicable to gene medicines such as antisense ODNs and adenovirus vectors. These results suggest that Atelocollagen may be appropriate for general use in high-throughput screening of large sets of gene medicines for functional analyses in mammalian cells.     

利用基因芯片技术研究两品种鸡脂肪组织差异表达基因

应用包含9024条鸡cDNA的表达谱芯片,对从两品种鸡脂肪组织抽提及纯化的mRNA进行芯片杂交,并对基因表达谱进行分析,旨在筛选高脂肉鸡和白耳蛋鸡脂肪组织差异表达的基因,探讨造成两品种体脂性状差异的分子生物学机理。结果按差异显著阳性标准分析,共筛选出差异表达基因67条,主要涉及脂类代谢、能量代谢、细胞骨架构成、转录和剪接因子以及蛋白质合成与分解等相关基因,此外,还筛选出一些尚未在GenBank上登陆的序列,推测可能是未知的新基因,它们在鸡脂类代谢的过程所起到的作用还需进一步实验证明。     

Expansion of the complement receptor gene family. Identification in the mouse of two new genes related to the CR1 and CR2 gene family

Human cDNA probes encoding the C3b/C4b complement receptor, CR1, have been used to identify, in the mouse, two new genes which are related to CR1 but which appear to encode a different protein product. These new mouse genes, arbitrarily designated mouse genes X and Y, hybridize specifically to three different cDNA probes derived from human CR1. The degree of hybridization homology between the mouse X and Y genes suggests they are very closely related to one another; however, the chromosomal localization of the mouse X gene to chromosome 8 and the mouse Y gene to chromosome 1 indicates they are distinct gene sequences. The mRNA species detected with the X and/or Y (X/Y) sequences are approximately 2000 bases in length, but vary in both quantity and size depending upon the tissue analyzed. DNA sequence analysis of a cDNA specific for the X and Y sequences indicates the mature protein(s) will contain the 60 amino acid consensus repeat characteristic of a group of other proteins including CR1, the C3d receptor (CR2), H, C4 binding protein (C4bp), the interleukin 2 (Il 2) receptor and others. The identity of the mouse X and Y genes, and the function of the proteins which they encode, is not known; however, the small size of the mRNA and the tissue specific expression suggests they do not encode mouse CR1 or CR2 but instead encode a related protein (or proteins) which is expressed in a wide variety of mouse tissues.