Specificity of sugar cane trehalase

An extract containing trehalase and invertase was prepared from apical internodes of sugar cane. The extract hydrolysed three glucosides: maltose, trehalose and sucrose. By reprecipitation with ammonium sulphate, maltase and trehalase activities appear to be due to different enzymes. As was also shown by differential inhibition and activation and by studies on the behaviour of both enzymes during growth, invertase and trehalase activities are attributed to different enzymes whose activities do not overlap. Invertase-free preparations confirm these results. Sucrose is a simple competitive inhibitor of sugar cane trehalase, excluding a regulatory role for this sugar. Sucrose was found at inhibitory levels in the first four apical internodes. A close correlation between sugar cane growth and invertase and trehalase levels was found in the apical internodes. Invertase has the greatest activity during growing, and trehalase reaches a maximum at maturity, prior to the flowering process. The high levels of trehalase in the flower suggest that the enzyme is involved in flowering or in related processes linked to seed formation.     

Cellular localization and proposed function of midgut trehalase in the silkworm larva, Bombyx mori

A sorbitol density gradient analysis with the aid of several marker enzymes demonstrated that midgut trehalase of the silkworm larvae. Bombyx mori, was localized in the microsomal membranes, but not in mitochondria, lysosomes and microvilli at the apical surface. Electron microscopic examination showed that trehalase-enriched membrane fraction consisted of heterogeneous mixtures of membrane vesicles derived from the endoplasmic reticulum and plasma membrane parts other than the microvillus membrane. The enzyme-histochemical stains of trehalase activity on the midgut section could be detected only at the basal surface of the epithelium against haemocoel. Such a specific localization was further confirmed by immunohistochemistry with the peroxidase-conjugated antibody technique. Thus, it is concluded that midgut trehalase of silkworm larvae is situated on the plasma membrane at the basal surface of the epithelium. An intact preparation of midgut incubated in vitro in the medium containing [(14)C]trehalose could hydrolyse trehalose into glucose and take it up into the cell, although some glucose was liberated into the medium when incubated for extended periods. These results suggest that midgut trehalase plays a physiological role in utilization of haemolymph trehalose not in nutrient absorption.     

Quantification of trehalose in biological samples with a conidial trehalase from the thermophilic fungus Humicola grisea var. thermoidea

The partially-purified, thermally-stable trehalase from conidia of Humicola grisea was highly specific for trehalose and was free of potentially interfering activities. The enzyme was fully stable when stored in solution at -15°C for at least 6 months. This preparation could be used to quantify trehalose from 0.05 to 1.25 mol/ml either in carbohydrate mixtures or in complex biological materials.M.J. Neves, H.F. Terenzi and J.A. Jorge are with Departmento de Biologia, Faculdade de Filosofia, Ciências e Letras de Ribeirao Preto, Universidade de São Paulo, 14040-901-Ribeirão Preto, São Paulo, Brazil; F.A. Leone is with Departamento de Quimica, Faculdade de Filosofia, Ciências e Letras de Ribeirão Preto, Universidade de São Paulo, 14040-901-Ribeirão Preto, São Paulo, Brazil.     

Chemical Genetics of AGC-kinases Reveals Shared Targets of Ypk1, Protein Kinase A and Sch9

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Highlights

• •Acute inhibition of growth-regulatory AGC-kinases Sch9, PKA and Ypk1.
• •Phospho-proteomic profiling of 6373 phsopho-sites.
• •Ypk1 regulates phospho-sites in RRxS/T-context and functionally overlaps with PKA.
• •Ypk1 and PKA activate trehalase activity of Nth1.

     

Molecular Cloning of cDNA for Trehalase from the European Honeybee,Apis mellifera L., and Its Heterologous Expression in Pichia pastoris

cDNA encoding the bound type trehalase of the European honeybee was cloned. The cDNA (3,001 bp) contained the long 5′ untranslated region (UTR) of 869 bp, and the 3′ UTR of 251 bp including a poly(A) tail, and the open reading frame of 1,881 bp consisting of 626 amino acid residues. The M _r of the mature enzyme comprised of 591 amino acids, excluded a signal sequence of 35 amino acid residues, was 69,177. Six peptide sequences analyzed were all found in the deduced amino acid sequence. The amino acid sequence exhibited high identity with trehalases belonging to glycoside hydrolase family 37. A putative transmembrane region similar to trehalase-2 of the silkworm was found in the C-terminal amino acid sequence. Recombinant enzyme of the trehalase was expressed in the methylotrophic yeast Pichia pastoris as host, and displayed properties identical to those of the native enzyme except for higher sugar chain contents. This is the first report of heterologous expression of insect trehalase.     

Decapping Scavenger (DcpS) enzyme: Advances in its structure,activity and roles in the cap-dependent mRNA metabolism

Decapping Scavenger (DcpS) enzyme rids eukaryotic cells of short mRNA fragments containing the 5′ mRNA cap structure, which appear in the 3′ → 5′ mRNA decay pathway, following deadenylation and exosome-mediated turnover. The unique structural properties of the cap, which consists of 7-methylguanosine attached to the first transcribed nucleoside by a triphosphate chain (m⁷GpppN), guarantee its resistance to non-specific exonucleases. DcpS enzymes are dimers belonging to the Histidine Triad (HIT) superfamily of pyrophosphatases. The specific hydrolysis of m⁷GpppN by DcpS yields m⁷GMP and NDP. By precluding inhibition of other cap-binding proteins by short m⁷GpppN-containing mRNA fragments, DcpS plays an important role in the cap-dependent mRNA metabolism. Over the past decade, lots of new structural, biochemical and biophysical data on DcpS has accumulated. We attempt to integrate these results, referring to DcpS enzymes from different species. Such a synergistic characteristic of the DcpS structure and activity might be useful for better understanding of the DcpS catalytic mechanism, its regulatory role in gene expression, as well as for designing DcpS inhibitors of potential therapeutic application, e.g. in spinal muscular atrophy.     

MOLECULAR CLONING OF SOLUBLE TREHALASE FROM Chironomus riparius LARVAE, ITS HETEROLOGOUS EXPRESSION IN Escherichia coli AND BIOINFORMATIC ANALYSIS

Trehalase is involved in the control of trehalose concentration, the main blood sugar in insects. Here, we describe the molecular cloning of the cDNA encoding for the soluble form of the trehalase from the midge larvae of Chironomus riparius, a well-known bioindicator of the quality of freshwater environments. Molecular cloning was achieved through multiple alignment of Diptera trehalase sequences, allowing the synthesis of internal homology-based primers; the complete open reading frame(ORF) was subsequently obtained through RACE-PCR(where RACE is rapid amplification of cDNA ends). The cDNA contained the 5' untranslated region (UTR), the 3' UTR including a poly(A) tail and the ORF of 1,725 bp consisting of 574 amino acid residues with a predicted molecular mass of 65,778 Da. Recombinant trehalase was successfully expressed in Escherichia coli as a His-tagged protein and purified on Ni-NTA affinity chromatography. Primary structure analysis showed a series of characteristic features shared by all insect trehalases, while three-dimensional structure prediction yielded the typical glucosidase fold, the two key residues involved in the catalytic mechanism being conserved. Production of recombinant insect trehalases opens the way to structural characterizations of the catalytic site, which might represent, among others, an element for reconsidering the enzyme as a target in pest insects' control.     

昆虫海藻糖酶的基因特性及功能研究进展

海藻糖酶(Treh)是昆虫能量代谢必不可少的一类酶, 亦是昆虫体内几丁质合成通路的第一个酶。其基因表达和酶活性直接与正常发育、 蜕皮、 变态以及繁殖等昆虫重要生理过程密切相关。目前已有多种昆虫的海藻糖酶基因被成功克隆, 从而发现昆虫海藻糖酶基因家族由多个成员组成。海藻糖酶基因所编码的蛋白大多数具有一个信号肽前导区, 部分蛋白拥有1~2个跨膜结构域, 根据是否具有跨膜结构, 可将其分为可溶性海藻糖酶(Treh1)和膜结合型海藻糖酶(Treh2)两类, 膜结合型海藻糖酶具有2个特有的标签序列, 即“PGGRFREFYYWDSY”和“QWDYPNAWPP”。海藻糖酶的主要功能是将胞外和胞内的海藻糖降解成葡萄糖, 为昆虫的生命活动提供能量。具体表现为两个方面, 一是参与昆虫几丁质合成途径, 从而调控表皮、 中肠等处的几丁质合成; 二是通过与激素的协同作用, 调控昆虫体内海藻糖和葡萄糖等糖类物质的浓度变化, 从而有效保护体内细胞的适应并渡过相应的逆境环境, 并提高其抗逆能力。鉴于海藻糖酶的重要功能, 其已成为害虫控制的潜在新靶标。不同类型海藻糖酶的功能研究及酶抑制剂的研发与应用将进一步推动害虫生物防治的发展。     

Protein phosphorylation and trehalase activation in Candida utilis

Abstract Candida utilis cells contain a regulatory trehalase enzyme (280 kDa) which can be activated by cAMP-dependent phosphorylation. A 100-fold purification of this enzyme activity results in the enrichment of a protein band of apparent M _r 70 000 as identified by sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE). This component is phosphorylated in vivo under conditions in which trehalase activation occurs in whole cells. It is concluded that the trehalase enzyme might be a tetramer, composed of 4 identical 70-kDa subunits.     

Association of Multiple Phosphorylated Proteins with the 14-3-3 Regulatory Hubs: Problems and Perspectives

14-3-3 proteins are well-known universal regulators binding a vast number of partners by recognizing their phosphorylated motifs, typically located within the intrinsically disordered regions. The abundance of such phosphomotifs ensures the involvement of 14-3-3 proteins in sophisticated protein–protein interaction networks that govern vital cellular processes. Thousands of 14-3-3 partners have been either experimentally identified or predicted, but the spatiotemporal hierarchy of the processes based on 14-3-3 interactions is not clearly understood. This is exacerbated by the lack of available structural information on full regulatory complexes involving 14-3-3, which resist high-resolution structural studies due to the presence of intrinsically disordered regions. Although deducing three-dimensional structures is of particular urgency, structural advances are lagging behind the rate at which novel 14-3-3 partners are discovered. Here I attempted to critically review the current state of the field and in particular to dissect the unknowns, focusing on questions that could help in moving the frontiers forward.