Protein tyrosine phosphatase profiling analysis of HIB-1B cells during brown adipogenesis

A number of evidence have been accumulated that the regulation of reversible tyrosine phosphorylation, which can be regulated by the combinatorial activity of protein tyrosine kinases (PTKs) and protein tyrosine phosphatases (PTPs), plays crucial roles in various biological processes including differentiation. There are a total of 107 PTP genes in the human genome, collectively referred to as the "PTPome." In this study, we performed PTP profiling analysis of the HIB-1B cell line, a brown preadipocyte cell line, during brown adipogenesis. Through RT-PCR and real-time PCR, several PTPs showing differential expression pattern during brown adipogenesis were identified. In the case of PTP-RE, it was shown to decrease significantly until 4 days after brown adipogenic differentiation, followed by a dramatic increase at 6 days. The overexpression of PTP-RE led to decreased brown adipogenic differentiation via reducing the tyrosine phosphorylation of the insulin receptor, indicating that PTP-RE functions as a negative regulator at the early stage of brown adipogenesis.     

MRFs家族基因在翘嘴鳜成体不同组织及器官中的表达特征

生肌调节因子(MRFs)家族成员包括MRF4、Myf5、Myogenin和MyoD,是肌肉形成的关键控制因素,其作为一种转录因子在肌肉的发育分化过程中发挥重要作用。本研究通过RT-qPCR方法分析MRFs家族基因在翘嘴鳜成体中不同组织及器官的表达情况,阐明其在肌肉组织中的特异性表达。结果显示:MRFs家族基因在成体翘嘴鳜肌肉、心脏、肝脏、脾脏、肾脏、肠道和脑组织及器官中均检测到表达,且在肌肉中的表达量显著高于其他组织及器官中的表达量(p<0.05)。为研究生肌调节因子在翘嘴鳜肌肉发育过程中的作用提供了基础资料。     

PRL-1 PTPase expression is developmentally regulated with tissue-specific patterns in epithelial tissues

The mechanisms controlling tyrosine phosphorylation of cellular proteins are important in the regulation of many cellular processes, including development and differentiation. Protein tyrosine phosphatases (PTPases) may be as important as protein tyrosine kinases (PTKs) in these processes. PRL-1 is a distinct PTPase originally identified as an immediate-early gene in liver regeneration whose expression is associated with growth in some tissues but with differentiation in others. We now demonstrate that the PRL-1 protein is expressed during development in a number of digestive epithelial tissues. It is expressed at variable time points in the developing intestine, but its expression is limited to the developing villus enterocytes. In the gastric epithelium, PRL-1 expression in the adult is restricted to zymogen cells. PRL-1 is also expressed in the developing liver and esophagus and in the epithelia of the kidney and lung. In each of these contexts, the expression of PRL-1 is associated with terminal differentiation, suggesting that it may play a role in this important developmental process.     

Human brain glycogen phosphorylase. Cloning, sequence analysis, chromosomal mapping, tissue expression, and comparison with the human liver and muscle isozymes

We have cloned the cDNA encoding a new isozyme of glycogen phosphorylase (1,4-D-glucan:orthosphosphate D-glucosyltransferase, EC 2.4.1.1) from a cDNA library prepared from a human brain astrocytoma cell line. Blot-hybridization analysis reveals that this message is preferentially expressed in human brain, but is also found at a low level in human fetal liver and adult liver and muscle tissues. Although previous studies have suggested that the major isozyme of phosphorylase found in all fetal tissues is the brain type, our data show that the predominant mRNA in fetal liver (24-week gestation) is the adult liver form. The protein sequence deduced from the nucleotide sequence of the brain phosphorylase cDNA is 862 amino acids long compared with 846 and 841 amino acids for the liver and muscle isozymes, respectively; the greater length of brain phosphorylase is entirely due to an extension at the far C-terminal portion of the protein. The muscle and brain isozymes share greater identity with regard to nucleotide and deduced amino acid sequences, codon usage, and nucleotide composition than either do with the liver sequence, suggesting a closer evolutionary relationship between them. Spot blot hybridization of the brain phosphorylase cDNA to laser-sorted human chromosome fractions, and Southern blot analysis of hamster/human hybrid cell line DNA reveals that the exact homolog of the newly cloned cDNA maps to chromosome 20, but that a slightly less homologous gene is found on chromosome 10 as well. The liver and muscle genes have previously been localized to chromosomes 14 and 11, respectively. This suggests that the phosphorylase genes evolved by duplication and translocation of a common ancestral gene, leading to divergence of elements controlling gene expression and of structural features of the phosphorylase proteins that confer tissue-specific functional properties.     

Evolutionary radiation pattern of novel protein phosphatases revealed by analysis of protein data from the completely sequenced genomes of humans, green algae, and higher plants

In addition to the major serine/threonine-specific phosphoprotein phosphatase, Mg(2+)-dependent phosphoprotein phosphatase, and protein tyrosine phosphatase families, there are novel protein phosphatases, including enzymes with aspartic acid-based catalysis and subfamilies of protein tyrosine phosphatases, whose evolutionary history and representation in plants is poorly characterized. We have searched the protein data sets encoded by the well-finished nuclear genomes of the higher plants Arabidopsis (Arabidopsis thaliana) and Oryza sativa, and the latest draft data sets from the tree Populus trichocarpa and the green algae Chlamydomonas reinhardtii and Ostreococcus tauri, for homologs to several classes of novel protein phosphatases. The Arabidopsis proteins, in combination with previously published data, provide a complete inventory of known types of protein phosphatases in this organism. Phylogenetic analysis of these proteins reveals a pattern of evolution where a diverse set of protein phosphatases was present early in the history of eukaryotes, and the division of plant and animal evolution resulted in two distinct sets of protein phosphatases. The green algae occupy an intermediate position, and show similarity to both plants and animals, depending on the protein. Of specific interest are the lack of cell division cycle (CDC) phosphatases CDC25 and CDC14, and the seeming adaptation of CDC14 as a protein interaction domain in higher plants. In addition, there is a dramatic increase in proteins containing RNA polymerase C-terminal domain phosphatase-like catalytic domains in the higher plants. Expression analysis of Arabidopsis phosphatase genes differentially amplified in plants (specifically the C-terminal domain phosphatase-like phosphatases) shows patterns of tissue-specific expression with a statistically significant number of correlated genes encoding putative signal transduction proteins.     

Testis-specific expression of a novel mouse defensin-like gene,Tdl

In order to isolate genes regulating sex differentiation of embryonic gonads, we have attempted to obtain genes specifically expressed in male embryonic gonads by means of subtractive hybridization screening, and we have cloned a novel mouse gene, Tdl. It potentially encodes a protein showing sequence homology to anti-microbial protein, beta-defensins. Tdl reveals structural features such as the six cysteine residues with invariant spacing, which are found in beta-defensins, but the overall amino acid similarity of Tdl to other members of the beta-defensin family is low. In addition, the Tdl gene shows genomic organization similar to that of other beta-defensin genes. We have found that Tdl is specifically expressed in Sertoli cell-lineage in seminiferous cords in embryonic testes, but not in embryonic ovaries after 12.5dpc when the sexual differentiation of gonads is initiated. Tdl is specifically expressed in gonads among adult tissues, and its expression persisted in Sertoli cells.     

Expression and tissue distribution of astacin-like squid metalloprotease (ALSM)

Astacin metalloprotease family members function in a wide variety of biologic events, including cell differentiation and morphogenesis during embryonic development and adult tissue differentiation. We previously isolated and characterized an astacin-like squid metalloprotease (ALSM). To elucidate the embryonic expression of ALSM, we performed immunohistochemical analysis with specific antibodies and examined the expression profiles of ALSM isoforms by in situ hybridization analysis. Tissue distribution and expression were also examined in adult spear squid. mRNA expression of ALSM isoforms I and III was first detected in newly hatched squid and was restricted to the liver. No mRNA signals were detected in other tissues even in adult squids. At the protein level, both isoforms were prominent in the liver of embryos and later in digestive organs of adult squid. Both isoforms were also detected in muscle tissues, including mantle and tentacle muscle. Staining for ALSM III was also identified in the iris and in tissues near the eye in squid embryos. However, no reactive bands were detected by immunoblotting of adult squid eyes. Thus, ALSM is initially expressed at the late stage of embryogenesis in spear squid, and expression is restricted to the liver. Thereafter, ALSM isoforms function in various tissues in an isoform-dependent manner.     

Structure, mapping and expression of the human gene encoding the homeodomain protein, SIX2

Vertebrate genes with sequence similarity to the Drosophila homeobox gene, sine oculis (so), constitute the SIX family. There is notable expression of members of this family in anterior neural structures, and several SIX genes have been shown to play roles in vertebrate and insect development, or have been implicated in maintenance of the differentiated state of tissues. Mutations in three of these genes in man (SIX5, SIX6 and SIX3) are associated with severe phenotypes, and therefore, the cloning of other human genes from this family is of interest. We have cloned and characterised the gene that encodes human SIX2, elucidated its gene structure and conducted expression studies in a range of tissues. SIX2 is widely expressed in the late first-trimester fetus, but has a limited range of expression sites in the adult. The expression pattern of SIX2 and its localisation to chromosome 2p15-p16 will be of use in assessing its candidacy in human developmental disorders.     

Analysis of the expression pattern of Mysidium columbiae wingless provides evidence for conserved mesodermal and retinal patterning processes among insects and crustaceans

The Wnt family includes a number of genes, such as wingless ( wg), which encode secreted glycoproteins that function in numerous developmental patterning processes. In order to gain a better understanding of crustacean pattern formation, a wg orthologue was cloned from the malacostracan crustacean Mysidium columbiae(mysid), and the expression pattern of this gene was compared with that of Drosophila wg. Although Drosophila wg is expressed in many developing tissues, such as the ventral neuroectoderm, M. columbiae wg (mcowg)expression is detected within only a subset of these tissues. mcowg is expressed in the dorsal part of each developing segment and within the developing eye, but not within the ventral neuroectoderm. Dorsal wg expression in Drosophila is required for heart and muscle development, and conservation of this dorsal wgexpression pattern suggests that mcowgmay function to pattern these tissues in mysids. Consistent with this, expression of Even-skipped (Eve) protein in heart precursor and muscle cells, which is dependent on Wg signaling in Drosophila, is also conserved in mysids. Within the developing mysid eye, mcowg is expressed in a pattern that is similar to the expression pattern of Drosophila wg in the fly eye disc. In Drosophila,Wg inhibits neural differentiation at the anterior margin of the eye disc and patterns the dorsal/ventral axis of the eye. These data indicate that mcowg may function similarly during mysid eye development. Analysis of mcowgexpression provides molecular evidence suggesting that the processes of heart, muscle, and eye patterning are likely to be conserved among insects and crustaceans.     

Cloning, characterization, and mapping of the gene encoding the human G protein gamma 2 subunit

G proteins play vital roles in cellular responses to external signals. The specificity of G protein-receptor interaction is mediated mostly by the gamma-subunit and the individual members of the gamma-subunit multigene family would hence be expected to each have a particular expression profile. In an experiment designed to isolate genes expressed predominantly in human testis we identified a cDNA fragment corresponding to the gamma2 gene. Although the protein sequence of the gamma2 subunit has previously been published, the cDNA sequence, expression pattern, genomic structure, and localisation of the human GNG2 gene have not been described. We report the complete sequence of the GNG2 cDNA which is 1066 bp long and contains an open reading frame encoding a protein of 71 amino acids. This protein is 100% homologous to the bovine, mouse, and rat G protein gamma2 subunit. The gene structure is very similar to that of other Ggamma-subunit genes in that there are two introns, one located in the 5' UTR and the other within the ORF. We show that this gene is expressed in a range of foetal tissues as well as adult testis, adrenal gland, brain, white blood cells and lung but not in adult liver, muscle, sperm, prostate gland nor in the testes of two different infertile patients. There is evidence that GNG2 is expressed in malignant tissues. Using two independent methods, we have mapped the human GNG2 gene to chromosome 14q21.     

Membrane-bound transferrin-like protein (MTf): structure, evolution and selective expression during chondrogenic differentiation of mouse embryonic cells.

Mouse membrane-bound transferrin-like protein (MTf) cDNA was cloned to examine its expression during chondrogenic differentiation in the mouse embryonic cell line ATDC5, and to analyze the phylogenetic relationships among the MTfs of four animal species and 23 other transferrin members. Phylogenetic analysis indicated that the MTf gene diverged from the common ancestor gene earlier than the genes of the other transferrins such as serum transferrin, lactoferrin and ovotransferrin, and that the divergence occurred after the divergence of vertebrates and invertebrates. MTf, as well as the other transferrins, consists of two repeated domains. The similarity between the N-terminal and the C-terminal domains of MTf is much higher than that of the other transferrins, although the five amino acid residues required for iron binding were not conserved in the C-terminal domain of MTf in contrast to the conservation of these residues in both domains of the other transferrins. Among various adult mouse tissues, MTf mRNA was expressed at the highest level in cartilage and at a moderate level in the testis. MTf mRNA was expressed only at very low levels in the brain, spleen, thymus, muscle, lung, skin and intestine, and hardly detected in the heart, kidney, stomach and liver. In cultures of the mouse ATDC5 cell line, MTf is developmentally expressed in parallel with the expression of type II collagen and aggrecan, in the pattern commensurate with the onset of chondrogenesis to form cartilage nodules. The structural characteristics and the expression pattern suggest that during development and in adult tissues, MTf has some functions that are different from those of other transferrins.     

银鲫果糖-1,6-二磷酸酶的分子克隆与表达分析

果糖-1,6-二磷酸酶(EC 3.1.3.11)是糖异生中的关键限速酶之一, 在糖代谢中起重要作用。哺乳动物存在肝脏型和肌肉型两种果糖-1,6-二磷酸酶同工酶,分别由Fbp1和Fbp2编码。银鲫作为我国重要的经济养殖鱼类, 尚无果糖-1,6-二磷酸酶基因的有关资料, 其组织分布特征和胚胎发育模式亦不清楚。本研究采用RACE方法从银鲫原肠胚SMART cDNA文库中扩增了果糖-1,6-二磷酸酶基因的全长cDNA, 其长度为1170 bp,编码337个氨基酸残基,多重序列比对和系统发育分析表明该基因为肝脏型果糖-1,6-二磷酶。RT-PCR分析虽在银鲫的肝、脑、心、脾、肾、肠、肌肉和卵巢组织中皆能检测到该基因的表达, 但以肝组织的表达量最高。Western Blot检测表明, 肝脏组织除有一条与其他组织(肌肉除外)共有的蛋白带之外,还有一条特异带;肌肉中有不同于其他组织的特异带。成熟卵子和不同发育阶段胚胎的RT-PCR和Western Blot分析都可检测到母源的CagFbp转录本和蛋白,且其转录本从原肠期开始上升, 到神经胚时迅速上升到较高水平, 其蛋白从尾芽期以后出现一条比母源蛋白分子量小、与肝脏的特异带大小基本相同的蛋白带。这些结果证实本研究克隆的CagFbp为肝脏型,且鱼类至少存在肝脏型和肌肉型两种果糖-1,6-二磷酸酶同工酶。       

PTPs versus PTKs: the redox side of the coin

The phosphorylation of tyrosine, and to a lesser extent threonine and serine, plays a key role in the regulation of signal transduction during a plethora of eukaryotic cell functions, including cell activation, cell-cycle progression, cytoskeletal rearrangement and cell movement, differentiation, apoptosis and metabolic homeostasis. In vivo, tyrosine phosphorylation is reversible and dynamic; the phosphorylation states are governed by the opposing activities of protein tyrosine kinases (PTKs)2 and protein tyrosine phosphatases (PTPs). Reactive oxygen species (ROS) act as cellular messengers in cellular processes such as mitogenic signal transduction, gene expression, regulation of cell proliferation, senescence and apoptosis. Redox regulated proteins include PTPs and PTKs, although with opposite regulation of enzymatic activity. Transient oxidation of thiols in PTPs leads to their inactivation by the formation of either an intramolecular S-S bridge or a sulfenyl-amide bond. Conversely, oxidation of PTKs leads to their activation, either by direct SH modification or, indirectly, by concomitant inhibition of PTPs that guides to sustained activation of PTKs. This review focuses on the redox regulation of both PTPs and PTKs and the interplay of their specular regulation.     

The nifk gene is widely expressed in mouse tissues and is up-regulated in denervated hind limb muscle

Denervation of skeletal muscle alters the expression of many genes, which may be important for establishing optimal conditions for reinnervation. Using the differential display technique we have attempted to discover neurally regulated genes in skeletal muscle. An mRNA that is up-regulated in denervated hind limb muscle was identified and cloned. The cDNA encodes an RNA-binding protein, which was discovered during the course of this work to be a nucleolar protein interacting with the fork-head associated domain of the proliferation marker protein Ki-67, and named NIFK. We show that the nifk gene is widely expressed in adult mouse tissues and that the expression is up-regulated in denervated hind limb muscle. No difference between expression in perisynaptic and extrasynaptic portions of muscle was observed. The widespread expression in adult tissues suggests that the NIFK protein has other functions in addition to its interaction with Ki-67, which is only expressed in proliferating cells.     

Distinct expression pattern of two related human proteins containing multiple types of protease-inhibitory modules

We have recently identified a gene (the WFIKKN gene) on human chromosome 16 (16p13.3) that encodes a secreted protein containing WAP-type, Follistatin/ Kazal type, Kunitz-type and NTR-type protease-inhibitory modules and an Immunoglobulin domain [Trexler et al., Proc. Natl. Acad. Sci. USA 98 (2001), 3705 - 3709]. In the present work we show that a gene on chromosome 17 encodes a WFIKKN-related protein (WFIKKNRP) that has the same domain organization as the WFIKKN protein. The exon-intron structure of the two genes is also similar as both genes have a single phase 0 intron that splits their WAP domains in equivalent positions. In view of the presence of several protease inhibitory modules in these proteins it seems likely that they serve to control the action of multiple types of proteases. The tissue expression pattern of the two proteins, however, is markedly different suggesting that they have distinct biological roles. Whereas the WFIKKN gene is expressed primarily in adult pancreas, liver and thymus but not in brain and ovary, significant expression of the WFIKKNRP gene is observed in ovary, testis and brain, but not in liver. Pronounced differences could also be seen in the case of fetal tissues: expression of the WFIKKN gene was highest in the lung, skeletal muscle and liver, whereas the WFIKKNRP gene was expressed primarily in brain, skeletal muscle, thymus and kidney.