Reversible inhibition of translation by Xenopus oocyte-specific proteins

A characteristic of growing oocytes of all animal species is the synthesis and accumulation of messenger RNA which is destined to be used primarily by the early embryo. The mechanism(s) which regulates the translation of this maternal mRNA remains unknown. However, the inability of the oocyte to translate all of its putative mRNA has been attributed to at least three limitations: (1) The rate of translation is limited by the availability of components of the translational apparatus other than mRNA, (2) the structural organization of the mRNA prevents translation, and (3) proteins associated with the mRNA prevent translation. Several investigators have suggested that proteins associated with maternal mRNA suppress translation in sea urchin eggs, although others claim that such results may be due to experimental artefacts. Oocyte-specific proteins have been identified in association with non-translating poly(A)+ mRNAs from Xenopus laevis oocytes, and we report here that when these proteins are reconstituted with mRNAs in vitro the translation of the mRNAs in vitro is reversibly repressed. The implication is that these proteins are involved in the regulation of translation of stored maternal mRNAs.     

Functional proteins from a random-sequence library

Functional primordial proteins presumably originated from random sequences, but it is not known how frequently functional, or even folded, proteins occur in collections of random sequences. Here we have used in vitro selection of messenger RNA displayed proteins, in which each protein is covalently linked through its carboxy terminus to the 3' end of its encoding mRNA, to sample a large number of distinct random sequences. Starting from a library of 6 x 1012 proteins each containing 80 contiguous random amino acids, we selected functional proteins by enriching for those that bind to ATP. This selection yielded four new ATP-binding proteins that appear to be unrelated to each other or to anything found in the current databases of biological proteins. The frequency of occurrence of functional proteins in random-sequence libraries appears to be similar to that observed for equivalent RNA libraries.     

An eIF-4A-like protein is a suppressor of an Escherichia coli mutant defective in 50S ribosomal subunit assembly

The assembly of ribosomes in bacterial cells is a complex process that remains poorly characterized. The in vitro assembly of active ribosomal subunits from purified RNA and protein components indicates that all of the information for proper assembly resides in the primary sequences of these macromolecules. On the other hand, the in vitro requirement of unphysiological heating steps suggests that this pathway may not accurately reflect the in vivo pathway, and that other proteins may be required. One approach to identify any additional proteins is to isolate second-site revertants of mutants defective in ribosome assembly. Ribosomal protein L24 is essential in the assembly of 50S subunits. We have identified an Escherichia coli gene, srmB, that, when expressed at high copy number, can suppress the effect of a temperature-sensitive lethal mutation in L24. The SrmB amino-acid sequence has sequence identity with mouse translation initiation factor eIF-4A and with the human nuclear protein, p68. The purified SrmB protein is a nucleic acid-dependent ATPase, like eIF-4A, but can also bind RNA in the absence of ATP and other auxiliary protein factors. The RNA dependent ATPase activity of SrmB suggests that like, eIF-4A, it could be involved in specific alterations of RNA secondary structure.     

Function of DnaJ and DnaK as chaperones in origin-specific DNA binding by RepA

Heat-shock proteins are normal constituents of cells whose synthesis is increased on exposure to various forms of stress. They are interesting because of their ubiquity and high conservation during evolution. Two families of heat-shock proteins, hsp60s and hsp70s, have been implicated in accelerating protein folding and oligomerization and also in maintaining proteins in an unfolded state, thus facilitating membrane transport. The Escherichia coli hsp70 analogue, DnaK, and two other heat-shock proteins, DnaJ and GrpE, are required for cell viability at high temperatures and are involved in DNA replication of phage lambda and plasmids P1 and F. These three proteins are involved in replication in vitro of P1 DNA along with many host replication proteins and the P1 RepA initiator protein. RepA exists in a stable protein complex with DnaJ containing a dimer each of RepA and DnaJ. We report here that DnaK and DnaJ mediate an alteration in the P1 initiator protein, rendering it much more active for oriP1 DNA binding.     

Reconstitution of a microtubule plus-end tracking system in vitro

The microtubule cytoskeleton is essential to cell morphogenesis. Growing microtubule plus ends have emerged as dynamic regulatory sites in which specialized proteins, called plus-end-binding proteins (+TIPs), bind and regulate the proper functioning of microtubules. However, the molecular mechanism of plus-end association by +TIPs and their ability to track the growing end are not well understood. Here we report the in vitro reconstitution of a minimal plus-end tracking system consisting of the three fission yeast proteins Mal3, Tip1 and the kinesin Tea2. Using time-lapse total internal reflection fluorescence microscopy, we show that the EB1 homologue Mal3 has an enhanced affinity for growing microtubule end structures as opposed to the microtubule lattice. This allows it to track growing microtubule ends autonomously by an end recognition mechanism. In addition, Mal3 acts as a factor that mediates loading of the processive motor Tea2 and its cargo, the Clip170 homologue Tip1, onto the microtubule lattice. The interaction of all three proteins is required for the selective tracking of growing microtubule plus ends by both Tea2 and Tip1. Our results dissect the collective interactions of the constituents of this plus-end tracking system and show how these interactions lead to the emergence of its dynamic behaviour. We expect that such in vitro reconstitutions will also be essential for the mechanistic dissection of other plus-end tracking systems.     

Interactions between HMG proteins (HMG1/2 and HMG14/17) and human ε-globin gene promoter (ε-promoter)

High mobility group (HMG) proteins are abundant non-histone proteins in the nuclei of eukaryocytes. It has been shown that HMG proteins may play important roles in the structure and function of chromatin. In the present study, thebinding of HMG proteins (HMG1/2 and HMG14/17) to the human ε-globin gene promoter (ε-promo- ter, -177-+1 bp) has been examined by using both the in vitro nucleosome reconstitution and the electrophoresis mobility shift assay (EMSA). We found that HMG1/2 proteins could bind to the naked ε-promoter DNA, however, HMG14/17 could not. Using the in vitro nucleosome recons- titution, we revealed that HMG14/17 could bind to the mononucleosome reconstituted in vitro with ε-promoter,whi- le HMG1/2 could not. Those results indicate that the binding of HMG proteins to ε-promoter is dynamic as the nucleo- some assembling and disassembling. Wespeculated that this selective binding of HMG proteins to ε-promoter might playa critical role in the regulation of ε-globin gene expression.     

Observation and Analysis of in vitro Expression of Mouse Heart Nuclear DNA Fragments by AFM

Using AFM,we observed linear chain-like complexes formed by some specific proteins and the multi-mRNAs during the in vitro expression of some active genes on the DNA fragments. The LDH mRNA in the multi-mRNA complex can in vitro translate LDH. Via AFM, we also discovered that nmRNA prepared from heart muscles, along with some specific proteins can form linear chain-like nmRNA complexes in which LDH mRNA can also translate LDH in vitro. Our work shows the prospective application of AFM in the research of the biological reaction of the active genes on the DNA fragments.     

Defective co-translational formation of disulphide bonds in protein disulphide-isomerase-deficient microsomes

The formation of disulphide bonds in mammalian secretory and cell-surface proteins occurs in the lumen of the endoplasmic reticulum and is believed to be catalysed by the enzyme protein disulphide-isomerase (PDI). The evidence for this physiological role for PDI is circumstantial and relates to the cell and tissue distribution of the enzyme, its developmental behaviour and its catalytic properties in vitro. A clear requirement for PDI in the correct folding or assembly of disulphide-bonded proteins during biosynthesis has not been demonstrated. We have prepared dog pancreas microsomes which are deficient in soluble lumenal proteins, including PDI, but which are still able to translocate and process proteins synthesized in vitro. Using the formation of intramolecular disulphide bonds during the in vitro synthesis of gamma-gliadin, a wheat storage protein, as a model, we have demonstrated that these microsomes are defective in co-translational formation of disulphide bonds. Reconstitution of these microsomes with purified PDI reverses this defect.     

猪垂体Poly（A）~＋RNA的制备及其体外翻译

本文用ＬｉＣｌ沉淀法提取了猪垂体总ＲＮＡ，经。ｏｌｉｇｏ（ｄＴ）－ｃｅｌｌｕｌｏｓｅ柱亲和层析，分离纯化了猪垂体Ｐｏｌｙ（Ａ）＋ＲＮＡ．用自制的兔网织红细胞体外翻译体系鉴定，表明该Ｐｏｌｙ／（Ａ）＋ＲＮＡ具有较高的翻译活性．ＳＤＳ－ＰＡＯＥ，放射自显影分析翻译产物提示，在制各的猪垂体Ｐｏｌｙ（Ａ）＋ＲＮＡ中，编码猪生长激素前体的ｍＲＮＡ占有较高的比例．     

Cell-free expression of functional Shaker potassium channels.

The functional activity of ion channels and other membrane proteins requires that the proteins be correctly assembled in a transmembrane configuration. Thus, the functional expression of ion channels, neurotransmitter receptors and complex membrane-limited signalling mechanisms from complementary DNA has required the injection of messenger RNA or transfection of DNA into Xenopus oocytes or other target cells that are capable of processing newly translated protein into the surface membrane. These approaches, combined with voltage-clamp analysis of ion channel currents, have been especially powerful in the identification of structure-function relationships in ion channels. But oocytes express endogenous ion channels, neurotransmitter receptors and receptor-channel subunits, complicating the interpretation of results in mRNA-injected eggs. Furthermore, it is difficult to control experimentally the membrane lipids and post-translational modifications that underlie the regulation and modulation of ion channels in intact cells. A cell-free system for ion channel expression is ideal for good experimental control of protein expression and modulatory processes. Here we combine cell-free protein translation, microsomal membrane processing of nascent channel proteins, and reconstitution of newly synthesized ion channels into planar lipid bilayers to synthesize, glycosylate, process into membranes, and record in vitro the activity of functional Shaker potassium channels.     

Sequence and domain structure of talin

Talin is a high-molecular-weight cytoskeletal protein concentrated at regions of cell-substratum contact and, in lymphocytes, at cell-cell contacts. Integrin receptors are involved in the attachment of adherent cells to extracellular matrices and of lymphocytes to other cells. In these situations, talin codistributes with concentrations of integrins in the cell surface membrane. Furthermore, in vitro binding studies suggest that integrins bind to talin, although with low affinity. Talin also binds with high affinity to vinculin, another cytoskeletal protein concentrated at points of cell adhesion. Finally, talin is a substrate for the Ca2(+)-activated protease, calpain II, which is also concentrated at points of cell-substratum contact. To learn more about the structure of talin and its involvement in transmembrane connections between extracellular adhesions and the cytoskeleton, we have cloned and sequenced murine talin. We describe a model for the structure of talin based on this sequence and other data. Homologies between talin and other proteins define a novel family of submembranous cytoskeleton-associated proteins all apparently involved in connections to the plasma membrane.     

Reconstitution of active dimeric ribulose bisphosphate carboxylase from an unfoleded state depends on two chaperonin proteins and Mg-ATP.

In vitro reconstitution of active ribulose bisphosphate carboxylase (Rubisco) from unfolded polypeptides is facilitated by the molecular chaperones: chaperonin-60 from Escherichia coli (groEL), yeast mitochondria (hsp60) or chloroplasts (Rubisco sub-unit-binding protein), together with chaperonin-10 from E. coli (groES), and Mg-ATP. Because chaperonins are ubiquitous, a conserved Mg-ATP-dependent mechanism exists that uses the chaperonins to facilitate the folding of some other proteins.     

Binding of yeast a1 and alpha 2 as a heterodimer to the operator DNA of a haploid-specific gene

The mating-type locus (MAT) encodes several DNA-binding proteins, which determine the three cell types of Saccharomyces cerevisiae: the a and alpha haploid cell types, and the a/alpha diploid cell type. One of the products of MAT, alpha 2, functions in two cell types. In alpha cells, alpha 2 represses the a-specific genes by binding to the operator as a dimer. In a/alpha diploid cells, alpha 2 acts with a1, a product of the other MAT allele, to repress a different set of genes, the haploid-specific genes. Until now, the nature of the interaction between a1 and alpha 2 was not known, although it had been suggested that alpha 2 may form a heterodimer with a1. I show, by using proteins synthesized in vitro, that a1 and alpha 2 bind the operator of a haploid-specific gene as a heterodimer. The ability of alpha 2 to form both homodimers and heterodimers with a1, each with a different DNA-binding specificity, explains the dual regulatory functions of alpha 2. This is the first example of regulation by heterodimerization among homeobox-containing proteins, a class that includes proteins responsible for the specification of segment identity in Drosophila, mammals and other eukaryotes.     

用AFM观察小白鼠心肌核DNA片段的基因体外表达和垃圾DNA的相互作用

用AFM直接现场观察、体外表达等实验技术组合,观察到小白鼠（Balb/c）心肌核DNA片段的基因在体外表达过程中形成的n mRNA（n=9）线型链状复合体,处于垃圾DNA片段的特定的“翻译平台”上,其每种mRNA两端非共价键分别结合自己编码蛋白质（即分子开关）,中间的编码序列均非共价结合完全可解离的翻译活性因子等多种蛋白质：这些蛋白质可能均由垃圾DNA片段的极复杂的立体结构所形成的、匹配协同的、专一性蛋白质通路所调控,该通路对蛋白质按顺序分别进行特异性双向调控.核内n mRNA线型链状复合体在体外可翻译出LDH等蛋白质,并显示n mRNA翻译的“群体效应”.用AFM还观察到胞质制取的n mRNA（n=12）线型链状复合体（无垃圾DNA存在）,体外翻译出少量LDH等蛋白质,并显示n mRNA翻译的＂群体效应＂.本工作展示了未来运用AFM观察体外表达等生物学反应,研究基因表达与调控机制及其与垃圾DNA相互作用的前景.     

Insulin rapidly stimulates tyrosine phosphorylation of a Mr-185,000 protein in intact cells

Phosphotyrosine-containing proteins are minor components of normal cells which appear to be associated primarily with the regulation of cellular metabolism and growth. The insulin receptor is a tyrosine-specific protein kinase, and one of the earliest detectable responses to insulin binding is activation of this kinase and autophosphorylation of its beta-subunit. Tyrosine autophosphorylation activates the phosphotransferase in the beta-subunit and increases its reactivity toward tyrosine phosphorylation of other substrates. When incubated in vitro with [gamma-32P]ATP and insulin, the purified insulin receptor phosphorylates various proteins on their tyrosine residues. However, so far no proteins other than the insulin receptor have been identified as undergoing tyrosine phosphorylation in response to insulin in an intact cell. Here, using anti-phosphotyrosine antibodies, we have identified a novel phosphotyrosine-containing protein of relative molecular mass (Mr) 185,000 (pp185) which appears during the initial response of hepatoma cells to insulin binding. In contrast to the insulin receptor, pp185 does not adhere to wheat-germ agglutininagarose or bind to anti-insulin receptor antibodies. Phosphorylation of pp185 is maximal within seconds after exposure of the cells to insulin and exhibits a dose-response curve similar to that of receptor autophosphorylation, suggesting that this protein represents the endogenous substrate for the insulin receptor kinase.     

Sperm chromatin proteomics identifies evolutionarily conserved fertility factors

Male infertility is a long-standing enigma of significant medical concern. The integrity of sperm chromatin is a clinical indicator of male fertility and in vitro fertilization potential: chromosome aneuploidy and DNA decondensation or damage are correlated with reproductive failure. Identifying conserved proteins important for sperm chromatin structure and packaging can reveal universal causes of infertility. Here we combine proteomics, cytology and functional analysis in Caenorhabditis elegans to identify spermatogenic chromatin-associated proteins that are important for fertility. Our strategy employed multiple steps: purification of chromatin from comparable meiotic cell types, namely those undergoing spermatogenesis or oogenesis; proteomic analysis by multidimensional protein identification technology (MudPIT) of factors that co-purify with chromatin; prioritization of sperm proteins based on abundance; and subtraction of common proteins to eliminate general chromatin and meiotic factors. Our approach reduced 1,099 proteins co-purified with spermatogenic chromatin, currently the most extensive catalogue, to 132 proteins for functional analysis. Reduction of gene function through RNA interference coupled with protein localization studies revealed conserved spermatogenesis-specific proteins vital for DNA compaction, chromosome segregation, and fertility. Unexpected roles in spermatogenesis were also detected for factors involved in other processes. Our strategy to find fertility factors conserved from C. elegans to mammals achieved its goal: of mouse gene knockouts corresponding to nematode proteins, 37% (7/19) cause male sterility. Our list therefore provides significant opportunity to identify causes of male infertility and targets for male contraceptives.     

An essential role for a phospholipid transfer protein in yeast Golgi function

Progression of proteins through the secretory pathway of eukaryotic cells involves a continuous rearrangement of macromolecular structures made up of proteins and phospholipids. The protein SEC14p is essential for transport of proteins from the yeast Golgi complex. Independent characterization of the SEC14 gene and the PIT1 gene, which encodes a phosphatidylinositol/phosphatidylcholine transfer protein in yeast, indicated that these two genes are identical. Phospholipid transfer proteins are a class of cytosolic proteins that are ubiquitous among eukaryotic cells and are distinguished by their ability to catalyse the exchange of phospholipids between membranes in vitro. We show here that the SEC14 and PIT1 genes are indeed identical and that the growth phenotype of a sec14-1ts mutant extends to the inability of its transfer protein to effect phospholipid transfer in vitro. These results therefore establish for the first time an in vivo function for a phospholipid transfer protein, namely a role in the compartment-specific stimulation of protein secretion.