Organismal complexity, cell differentiation and gene expression: human over mouse

We present a molecular and cellular phenomenon underlying the intriguing increase in phenotypic organizational complexity. For the same set of human–mouse orthologous genes (11 534 gene pairs) and homologous tissues (32 tissue pairs), human shows a greater fraction of tissue-specific genes and a greater ratio of the total expression of tissue-specific genes to housekeeping genes in each studied tissue, which suggests a generally higher level of evolutionary cell differentiation (specialization). This phenomenon is spectacularly more pronounced in those human tissues that are more directly involved in the increase of complexity, longevity and body size (i.e. it is reflected on the organismal level as well). Genes with a change in expression breadth show a greater human–mouse divergence of promoter regions and encoded proteins (i.e. the functional genomics data are supported by the structural analysis). Human also shows the higher expression of translation machinery. The upstream untranslated regions (5′UTRs) of human mRNAs are longer than mouse 5′UTRs (even after correction for the difference in genome sizes) and contain more uAUG codons, which suggest a more complex regulation at the translational level in human cells (and agrees well with the augmented cell specialization).     

Phylogenetic comparison of metabolic capacities of organisms at genome level

Horizontal gene transfer (HGT) has been shown to widely spread in organisms by comparative genomic studies. However, its effect on the phylogenetic relationship of organisms, especially at a system level of different cellular functions, is still not well understood. In this work, we have constructed phylogenetic trees based on the enzyme, reaction, and gene contents of metabolic networks reconstructed from annotated genome information of 82 sequenced organisms. Results from different phylogenetic distance definitions and based on three different functional subsystems (i.e., metabolism, cellular processes, information storage and processing) were compared. Results based on the three different functional subsystems give different pictures on the phylogenetic relationship of organisms, reflecting the different extents of HGT in the different functional systems. In general, horizontal transfer is prevailing in genes for metabolism, but less in genes for information processing. Nevertheless, the major results of metabolic network-based phylogenetic trees are in good agreement with the tree based on 16S rRNA and genome trees, confirming the three domain classification and the close relationship between eukaryotes and archaea at the level of metabolic networks. These results strongly support the hypothesis that although HGT is widely distributed, it is nevertheless constrained by certain pre-existing metabolic organization principle(s) during the evolution. Further research is needed to identify the organization principle and constraints of metabolic network on HGT which have large impacts on understanding the evolution of life and in purposefully manipulating cellular metabolism.     

Lactose metabolism in Lactobacillus bulgaricus: analysis of the primary structure and expression of the genes involved.

The genes coding for the lactose permease and beta-galactosidase, two proteins involved in the metabolism of lactose by Lactobacillus bulgaricus, have been cloned, expressed, and found functional in Escherichia coli. The nucleotide sequences of these genes and their flanking regions have been determined, showing the presence of two contiguous open reading frames (ORFs). One of these ORFs codes for the lactose permease gene, and the other codes for the beta-galactosidase gene. The lactose permease gene is located in front of the beta-galactosidase gene, with 3 bp in the intergenic region. The two genes are probably transcribed as one operon. Primer extension studies have mapped a promoter upstream from the lactose permease gene but not the beta-galactosidase gene. This promoter is similar to those found in E. coli with general characteristics of GC-rich organisms. In addition, the sequences around the promoter contain a significantly higher number of AT base pairs (80%) than does the overall L. bulgaricus genome, which is rich in GC (GC content of 54%). The amino acid sequences obtained from translation of the ORFs are found to be highly homologous (similarity of 75%) to those from Streptococcus thermophilus. The first 460 amino acids of the lactose permease shows homology to the melibiose transport protein of E. coli. Little homology was found between the lactose permease of L. bulgaricus and E. coli, but the residues which are involved in the binding and the transport of lactose are conserved. The carboxy terminus is similar to that of the enzyme III of several phosphoenolpyruvate-dependent phosphotransferase systems.     

激活Toll样受体2可以促进胃癌细胞中的OXPHOS和糖酵解

目的:调查TLR家族中哪种TLR受体的配体依赖性激活可引起胃癌细胞的代谢重编程。方法:通过实时荧光定量PCR(RT-qPCR)和蛋白质印迹(WB)在一组人GC细胞中测量TLR家族成员的表达。通过进行Seahorse生物能测定以及测量L-乳酸和活性氧(ROS)的产生,确定激动剂对不同TLR(TLR2、4、9)诱导的人GC细胞的代谢变化;通过RT-qPCR在被刺激的GC细胞中分析了涉及氧化磷酸化和糖酵解的基因的表达;通过Western印迹表征SOD2的表达。结果:由合成分子或全病原体抗原激活的TLR2信号传导增强了胃癌细胞中高表达TLR2的细胞株的糖酵解活性和线粒体呼吸,而配体诱导的TLR4和TLR9活化抑制了线粒体呼吸或细胞外酸化率。同时,涉及葡萄糖代谢和氧化还原系统调节的基因,例如HIF1A,PFKFB3和SOD2,在TLRs下游被上调。结论:由配体诱导的特定TLRs的激活介导了人类GC细胞中不同的代谢表型。TLR2是唯一同时促进OXPHOS和糖酵解的家族成员,这可能导致肿瘤进展。     

Detailed structural-functional analysis of the Krüppel-like factor 16 (KLF16) transcription factor reveals novel mechanisms for silencing Sp/KLF sites involved in metabolism and endocrinology

Krüppel-like factor (KLF) proteins have elicited significant attention due to their emerging key role in metabolic and endocrine diseases. Here, we extend this knowledge through the biochemical characterization of KLF16, unveiling novel mechanisms regulating expression of genes involved in reproductive endocrinology. We found that KLF16 selectively binds three distinct KLF-binding sites (GC, CA, and BTE boxes). KLF16 also regulated the expression of several genes essential for metabolic and endocrine processes in sex steroid-sensitive uterine cells. Mechanistically, we determined that KLF16 possesses an activation domain that couples to histone acetyltransferase-mediated pathways, as well as a repression domain that interacts with the histone deacetylase chromatin-remodeling system via all three Sin3 isoforms, suggesting a higher level of plasticity in chromatin cofactor selection. Molecular modeling combined with molecular dynamic simulations of the Sin3a-KLF16 complex revealed important insights into how this interaction occurs at an atomic resolution level, predicting that phosphorylation of Tyr-10 may modulate KLF16 function. Phosphorylation of KLF16 was confirmed by in vivo (32)P incorporation and controlled by a Y10F site-directed mutant. Inhibition of Src-type tyrosine kinase signaling as well as the nonphosphorylatable Y10F mutation disrupted KLF16-mediated gene silencing, demonstrating that its function is regulatable rather than constitutive. Subcellular localization studies revealed that signal-induced nuclear translocation and euchromatic compartmentalization constitute an additional mechanism for regulating KLF16 function. Thus, this study lends insights on key biochemical mechanisms for regulating KLF sites involved in reproductive biology. These data also contribute to the new functional information that is applicable to understanding KLF16 and other highly related KLF proteins.     

Expression levels of candidate genes for intramuscular fat deposition in two Banna mini-pig inbred lines divergently selected for fatness traits

Intramuscular fat (IMF) content plays an important role in meat quality. Many genes involved in lipid and energy metabolism were identified as candidate genes for IMF deposition, since genetic polymorphisms within these genes were associated with IMF content. However, there is less information on the expression levels of these genes in the muscle tissue. This study aimed at investigating the expression levels of sterol regulating element binding protein-1c (SREBP-1c), diacylglycerol acyltransferase (DGAT-1), heart-fatty acids binding protein (H-FABP), leptin receptor (LEPR) and melanocortin 4 receptor (MC4R) genes and proteins in two divergent Banna mini-pig inbred lines (BMIL). A similar growth performance was found in both the fat and the lean BMIL. The fat meat and IMF content in the fat BMIL were significantly higher than in the lean BMIL, but the lean meat content was lower. The serum triacylglycerol (TAG) and free fatty acid (FFA) contents were significantly higher in the fat than in the lean BMIL. The expression levels of SREBP-1c, DGAT-1 and H-FABP genes and proteins in fat BMIL were increased compared to the lean BMIL. However, the expression levels of LEPR and MC4R genes and proteins were lower.     

Role of 5′‐ and 3′‐untranslated regions of mRNAs in human diseases

Protein synthesis is often regulated at the level of initiation of translation, making it a critical step. This regulation occurs by both the cis‐regulatory elements, which are located in the 5′‐ and 3′‐UTRs (untranslated regions), and trans‐acting factors. A breakdown in this regulation machinery can perturb cellular metabolism, leading to various physiological abnormalities. The highly structured UTRs, along with features such as GC‐richness, upstream open reading frames and internal ribosome entry sites, significantly influence the rate of translation of mRNAs. In this review, we discuss how changes in the cis‐regulatory sequences of the UTRs, for example, point mutations and truncations, influence expression of specific genes at the level of translation. Such modifications may tilt the physiological balance from healthy to diseased states, resulting in conditions such as hereditary thrombocythaemia, breast cancer, fragile X syndrome, bipolar affective disorder and Alzheimer's disease. This information tends to establish the crucial role of UTRs, perhaps as much as that of coding sequences, in health and disease.     

Binding sites of miRNA on the overexpressed genes of oral cancer using 7mer-seed match

The microRNAs having a length of?~?19–22 nucleotides are the small, non-coding RNAs. The evolution of microRNAs in many disorders may hold the key to tackle complex challenges. Oral cancer belongs to the group of head and neck cancer. It occurs in the mouth region that appears as an ulcer. In this study, we collected information on the overexpressed genes of oral cancer. The coding sequences of the genes were derived from NCBI and the entire set of human microRNAs present in miRBASE 21 was retrieved. The human microRNAs that can target the overexpressed genes of oral cancer were determined with the aid of our in-house software. The interaction between microRNAs and the overexpressed genes was evaluated with 7mer-m8 model of microRNA targeting. The genes DKK1 and APLN paired with only one miRNA i.e., miR-447 and miR-6087, respectively. But the genes INHBA and MMP1 were found to be targeted by 2 miRNAs, while the genes FN1, FAP, TGFPI, COL4A1, COL4A2, and LOXL2 were found to be targeted by 16, 5, 9, 18, 29, and 11 miRNAs. Subsequently, several measures such as free energy, translation efficiency, and cosine similarity metric were used to estimate the binding process. It was found that the target region’s stability was higher than the upstream and downstream zones. The overexpressed genes’ GC contents were calculated, revealing that the codons in target miRNA region were overall GC rich as well as GC3 rich. Lastly, gene ontology was performed to better understand each gene’s involvement in biological processes, molecular function, and cellular component. Our study showed the role of microRNAs in gene repression, which could possibly aid in the prognosis and diagnosis of oral cancer.

     

Identification of TTA codon containing genes in <Emphasis Type="Italic">Frankia</Emphasis> and exploration of the role of tRNA in regulating these genes

The TTA codon, one of the six available codons for the amino acid leucine, is the rarest codon among the high GC genomes of Actinobacteria including Frankia. This codon has been implicated in various regulatory mechanisms involving secondary metabolism and morphological development. TTA-mediated gene regulation is well documented in Streptomyces coelicolor, but that role has not been investigated in other Actinobacteria including Frankia. Among the various Actinomycetes with a GC content of more than 70%, Frankia genomes had the highest percentages of TTA-containing genes ranging from 5.2 to 10.68% of the genome. In contrast, TTA-bearing genes comprised 1.7, 3.4 and 4.1% of the Streptomyces coelicolor, S. avermitilis and Nocardia farcinia genomes, respectively. We analyzed their functional role, evolutionary significance, horizontal acquisition and the codon-anticodon interaction. The TTA-bearing genes were found to be well represented in metabolic genes involved in amino acid transport and secondary metabolism. A reciprocal Blast search reveal that many of the TTA-bearing genes have orthologs in the other Frankia genomes, and some of these orthologous genes also have a TTA codon in them. The gene expression level of TTA-containing genes was estimated by the use of the codon adaption index (CAI), and the CAI values were found to have a positive correlation with the GC3 (GC content at the 3rd codon position). A full-atomic 3D model of the leucine tRNA recognizing the TTA (UUA) codon was generated and utilized for in silico docking to determine binding affinity in codon-anticodon interaction. We found a proficient codon-anticodon interaction for this codon which is perhaps why so many genes hold on to this rare codon without compromising their translational efficiency.     

Storage,Photosynthesis, and Growth: The Conditional Nature of Mutations Affecting Starch Synthesis and Structure in Chlamydomonas

Growth-arrested Chlamydomonas cells accumulate a storage polysaccharide that bears strong structural and functional resemblance to higher plant storage starch. It is synthesized by similar enzymes and responds in an identical fashion to the presence of mutations affecting these activities. We found that log-phase photosynthetically active algae accumulate granular [alpha](1->4)-linked, [alpha](1->6)-branched glucans whose shape, cellular location, and structure differ markedly from those of storage starch. That synthesis of these two types of polysaccharides is controlled by both a common and a specific set of genes was evidenced by the identification of a new Chlamydomonas (STA4) locus specifically involved in the biosynthesis of storage starch. Mutants defective in STA4 accumulated a new type of high-amylose storage starch displaying an altered amylopectin chain size distribution. It is expected that the dual nature and functions of starch synthesis in unicellular green algae will yield new insights into the biological reasons for the emergence of starch in the eukaryotic plant cell.     

烟草叶片对不同光质短期应答的代谢轮廓

在烟草上部叶片生理成熟期给以白、紫外A、蓝、绿、黄、红6种LED灯光处理,研究了烟草叶片对不同光质的短期应答.结果表明: 采用非靶标检测方法共检测到68种GC/MS(气相色谱/质谱)稳定的代谢产物,在PLS-DA得分图中,6种光处理的样品被明显分开;有61种在质谱库中得到鉴定,其中45种代谢物质含量在不同光处理间存在显著性差异,主要为有机酸类、糖类、TCA循环中间产物、氨基酸类等初级代谢产物;采用差异性代谢物的热力图及聚类分析将其分为5类,同时也将6个处理明显分开,其中红、蓝光处理差异最为明显,除B类物质外,其他4类均以红光处理高于蓝光处理.采用靶标性检测方法测定了3种生物碱、5种多酚及茄尼醇的含量,4种(加上非靶标测定到的烟碱)生物碱在不同光质处理间的变化趋势一致,红光和黄光明显促进了生物碱积累;莰菲醇基芸香苷和芸香苷在不同处理之间的变化趋势一致,以蓝光处理最低、黄光最高,光质对其他3种多酚的影响各异;黄光明显抑制了茄尼醇的积累,蓝光处理的叶片中茄尼醇含量最高.说明光质变化对烟草脂肪酸代谢、糖代谢、生物碱代谢、氨基酸代谢、TCA循环和莽草酸途径等多条代谢途径均有显著的影响.