Tools for Fungal Proteomics: Multifunctional Neurospora Vectors for Gene Replacement, Protein Expression and Protein Purification

The completion of genome-sequencing projects for a number of fungi set the stage for detailed investigations of proteins. We report the generation of versatile expression vectors for detection and isolation of proteins and protein complexes in the filamentous fungus Neurospora crassa. The vectors, which can be adapted for other fungi, contain C- or N-terminal FLAG, HA, Myc, GFP, or HAT–FLAG epitope tags with a flexible poly-glycine linker and include sequences for targeting to the his-3 locus in Neurospora. To introduce mutations at native loci, we also made a series of knock-in vectors containing epitope tags followed by the selectable marker hph (resulting in hygromycin resistance) flanked by two loxP sites. We adapted the Cre/loxP system for Neurospora, allowing the selectable marker hph to be excised by introduction of Cre recombinase into a strain containing a knock-in cassette. Additionally, a protein purification method was developed on the basis of the HAT–FLAG tandem affinity tag system, which was used to purify HETEROCHROMATIN PROTEIN 1 (HP1) and associated proteins from Neurospora. As expected on the basis of yeast two-hybrid and co-immunoprecipitation (Co-IP) experiments, the Neurospora DNA methyltransferase DIM-2 was found in a complex with HP1. Features of the new vectors allowed for verification of an interaction between HP1 and DIM-2 in vivo by Co-IP assays on proteins expressed either from their native loci or from the his-3 locus.     

Construction and application of epitope- and green fluorescent protein-tagging integration vectors for Bacillus subtilis

Here we describe the construction and application of six new tagging vectors allowing the fusion of two different types of tagging sequences, epitope and localization tags, to any Bacillus subtilis protein. These vectors are based on the backbone of pMUTIN2 and replace the lacZ gene with tagging sequences. Fusion of the tagging sequences occurs by PCR amplification of the 3' terminal part of the gene of interest (about 300 bp), insertion into the tagging vector in such a way that a fusion protein will be synthesized upon integration of the whole vector via homologous recombination with the chromosomal gene. Three of these tagging sequences (FLAG, hemagglutinin, and c-Myc) allow the covalent addition of a short epitope tag and thereby detection of the fusion proteins in immunoblots, while three other tags (green fluorescent protein(+), yellow fluorescent protein, and cyan fluorescent protein) are helpful in assigning proteins within one of the compartments of the cell. The versatility of these vectors was demonstrated by fusing these tags to the cytoplasmically located HtpG and the inner membrane protein FtsH.     

Construction and Application of Epitope- and Green Fluorescent Protein-Tagging Integration Vectors for Bacillus subtilis

Here we describe the construction and application of six new tagging vectors allowing the fusion of two different types of tagging sequences, epitope and localization tags, to any Bacillus subtilis protein. These vectors are based on the backbone of pMUTIN2 and replace the lacZ gene with tagging sequences. Fusion of the tagging sequences occurs by PCR amplification of the 3′ terminal part of the gene of interest (about 300 bp), insertion into the tagging vector in such a way that a fusion protein will be synthesized upon integration of the whole vector via homologous recombination with the chromosomal gene. Three of these tagging sequences (FLAG, hemagglutinin, and c-Myc) allow the covalent addition of a short epitope tag and thereby detection of the fusion proteins in immunoblots, while three other tags (green fluorescent protein⁺, yellow fluorescent protein, and cyan fluorescent protein) are helpful in assigning proteins within one of the compartments of the cell. The versatility of these vectors was demonstrated by fusing these tags to the cytoplasmically located HtpG and the inner membrane protein FtsH.     

High-throughput Gene Tagging in Trypanosoma brucei

Improvements in mass spectrometry, sequencing and bioinformatics have generated large datasets of potentially interesting genes. Tagging these proteins can give insights into their function by determining their localization within the cell and enabling interaction partner identification. We recently published a fast and scalable method to generate Trypanosoma brucei cell lines that express a tagged protein from the endogenous locus. The method was based on a plasmid we generated that, when coupled with long primer PCR, can be used to modify a gene to encode a protein tagged at either terminus. This allows the tagging of dozens of trypanosome proteins in parallel, facilitating the large-scale validation of candidate genes of interest. This system can be used to tag proteins for localization (using a fluorescent protein, epitope tag or electron microscopy tag) or biochemistry (using tags for purification, such as the TAP (tandem affinity purification) tag). Here, we describe a protocol to perform the long primer PCR and the electroporation in 96-well plates, with the recovery and selection of transgenic trypanosomes occurring in 24-well plates. With this workflow, hundreds of proteins can be tagged in parallel; this is an order of magnitude improvement to our previous protocol and genome scale tagging is now possible.     

A PCR-based strategy to generate yeast strains expressing endogenous levels of amino-terminal epitope-tagged proteins

An epitope tag introduced to a gene of interest (GOI) greatly increases the ease of studying cellular proteins. Rapid PCR-based strategies for epitope tagging a protein's C-terminus at its native gene locus are widely used in yeast. C-terminal epitope tagging is not suitable for all proteins, however. Epitope tags fused to the C-terminus can interfere with function of some proteins or can even be removed by C-terminal protein processing. To overcome such problems, proteins can be tagged with epitopes at their amino-termini, but generating yeast strains expressing N-terminal epitope tagged genes under control of the endogenous promoter at the native locus is comparatively more difficult. Strategies to introduce N-terminal epitope tags have been reported previously but often introduce additional sequences other than the epitope tag into the genome. Furthermore, N-terminal tagging of essential genes by current methods requires formation of diploid strains followed by tetrad dissection or expression of an additional copy of the GOI from a plasmid. The strategies described here provide a quick, facile means of epitope tagging the N-terminus of both essential and nonessential genes in a two-step PCR-based procedure. The procedure has the significant advantage of leaving tagged genes under the control of their endogenous promoters, and no additional sequences other than the epitope tag encoding nucleotides are inserted into the genome.     

Peptides from the SARS-associated coronavirus as tags for protein expression and purification

Protein tagging with a peptide is a commonly used technique to facilitate protein detection and to carry out protein purification. Flexibility with respect to the peptide tag is essential since no single tag suites all purposes. This report describes the usage of two short peptides from the SARS-associated coronavirus nucleocapsid (SARS-N) protein as protein tags. Plasmids for the generation of tagged proteins were generated by ligating synthetic oligonucleotides for the peptide-coding regions downstream of the protein coding sequence. The data show recognition of prokaryotically expressed HIV-1 Gag/p24 fusion protein by Western blot and efficient affinity purification using monoclonal antibodies against the tags. The SARS peptide antibody system described presents an alternative tagging opportunity in the growing field of protein science.     

Tagging of Weakly Expressed Toxoplasma gondii Calcium‐Related Genes with High‐Affinity Tags

Calcium ions regulate a diversity of cellular functions in all eukaryotes. The cytosolic Ca²⁺ concentration is tightly regulated at the physiological cytosolic concentration of 50–100 nm . The Toxoplasma gondii genome predicts the presence of several genes encoding potential Ca²⁺ channels, pumps, and transporters. Many of these genes are weakly expressed and likely tightly regulated due to their potential impact to the physiology of the cell. Endogenous tagging has been widely used to localize proteins in T. gondii but low level of expression of many of them makes visualization of tags difficult and sometimes impossible. The use of high‐performance tags for labeling proteins expressed at low level is ideal for investigating the localization of these gene products. We designed a Carboxy‐terminus tagging plasmid containing the previously characterized “spaghetti monster‐HA” (smHA) or “spaghetti monster‐MYC” (smMYC) tags. These tags consist of 10 copies of a single epitope (HA or MYC) inserted into a darkened green fluorescence protein scaffold. We localized six proteins of various levels of expression. Clonal lines were isolated and validated by PCR, western blot, and immunofluorescence analyses. Some gene products were only visible when tagged with smHA and in one case the smHA revealed a novel localization previously undetected.     

新型酵母蛋白表位标记和基因敲除质粒系统的构建及可行性验证

【目的】构建一套用于酿酒酵母基因功能研究的质粒。该套质粒结合pUG系列和pFA6a系列的优点,同时采用同尾酶实现蛋白表位标签的串联插入。【方法】利用PCR技术分别克隆pUG系列质粒的lox P位点、pFA6a质粒多酶切位点和ADH1终止子模块;通过重组连接各片段,构建pCLHN-TRP和pCLHN-URA质粒。在此基础上利用同尾酶实现多种蛋白表位标签的单个或串联重复插入,获得一系列蛋白表位标记质粒。最后,以ATG1、COX4和NHX1为例验证本质粒系列的性能。【结果】在本项工作中,我们共构建2种基因敲除用质粒和17种表位标记用质粒(涵盖1-8 FLAG、1-12 V5、3-9 HA、2-8MYC、GFP和m Cherry)。在几个靶基因上的应用证实了本套质粒的实用性。尤其值得指出的是,通过组合采用不同重复度的串联表位标签,在同一张膜上同时检测表达差异极大的不同蛋白而不使高表达蛋白信号饱和成为可能。【结论】本文所构建的pCLHN质粒系列是对现有酵母质粒工具的有益补充。     

Cloning and analysis of a gene cluster from Streptomyces coelicolor that causes accelerated aerial mycelium formation in Streptomyces lividans.

We describe the cloning and analysis of two overlapping DNA fragments from Streptomyces coelicolor that cause aerial mycelium to appear more rapidly than usual when introduced into Streptomyces lividans on a low-copy-number plasmid vector. Colonies of S. lividans TK64 harboring either clone produce visible aerial mycelia after only 48 h of growth, rather than the usual 72 to 96 h. From deletion and sequence analysis, this rapid aerial mycelium (Ram) phenotype appears to be due to a cluster of three genes that we have designated ramA, ramB, and ramR. Both ramA and ramB potentially encode 65-kDa proteins with homology to ATP-dependent membrane-translocating proteins. A chromosomal ramB disruption mutant of S. lividans was found to be severely defective in aerial mycelium formation. ramR could encode a 21-kDa protein with significant homology to the UhpA subset of bacterial two-component response regulator proteins. The overall organization and potential proteins encoded by the cloned DNA suggest that this is the S. coelicolor homolog of the amf gene cluster that has been shown to be important for aerial mycelium formation in Streptomyces griseus. However, despite the fact that the two regions probably have identical functions, there is relatively poor homology between the two gene clusters at the DNA sequence level.     

Fluorescent labeling of membrane proteins on the surface of living cells by a self-catalytic glutathione S-transferase omega 1 tag

Imaging a specific protein of interest in live cell has versatile applications in biological research. Recently, diverse chemical tags have been developed to overcome the limits of autofluorescence protein (FP) tags. However, current chemical methods still need to be progressed to compete with FPs in the scope of specificity and convenience in staining procedure. We report a novel protein tagging method that provides a convenient and specific fluorescent labeling of membrane proteins. Ω tag is developed by employing a mammalian enzyme glutathione sulfur-transferase omega 1 (GSTO1) and its partner dye, 5-bromomethyl fluorescein (BMF). Ω-tagged membrane proteins were labeled by BMF efficiently for live cell imaging and in-gel analysis. Endocytosis of epidermal growth factor receptor (EGFR) was successfully visualized by using this Ω tagging system. Ω tag will provide a convenient tool for the physiological study of membrane proteins in live cells.     

Characterization of a new ScbR-like γ-butyrolactone binding regulator (SlbR) in Streptomyces coelicolor

γ-Butyrolactones in Streptomyces are well recognized as bacterial hormones, and they affect secondary metabolism of Streptomyces. γ-Butyrolactone receptors are considered important regulatory proteins, and various γ-butyrolactone synthases and receptors have been reported in Streptomyces. Here, we characterized a new regulator, SCO0608, that interacted with SCB1 (γ-butyrolactone of Streptomyces coelicolor) and bound to the scbR/A and adpA promoters. The SCO0608 protein sequences are not similar to those of any known γ-butyrolactone binding proteins in Streptomyces such as ScbR from S. coelicolor or ArpA from Streptomyces griseus. Interestingly, SCO0608 functions as a repressor of antibiotic biosynthesis and spore formation in R5 complex media. We showed the existence of another type of γ-butyrolactone receptor in Streptomyces, and this SCO0608 was named ScbR-like γ-butyrolactone binding regulator (SlbR) in S. coelicolor.     

Cloning and nucleotide sequence of the Streptomyces coelicolor gene encoding glutamine synthetase

The Streptomyces coelicolor glutamine synthetase (GS) structural gene (glnA) was cloned by complementing the glutamine growth requirement of an Escherichia coli strain containing a deletion of its glnALG operon. Expression of the cloned S. coelicolor glnA gene in E. coli cells was found to require an E. coli plasmid promoter. The nucleotide sequence of an S. coelicolor 2280-bp DNA segment containing the glnA gene was determined and the complete glnA amino acid sequence deduced. Comparison of the derived S. coelicolor GS protein sequence with the amino acid sequences of GS from other bacteria suggests that the S. coelicolor GS protein is more similar to the GS proteins from Gram-negative bacteria than it is with the GS proteins from two Gram-positive bacteria, Bacillus subtilis and Clostridium acetobutylicum.     

Characterization of an autonomously replicating region from the Streptomyces lividans chromosome.

The chromosomal replication origin of the plasmidless derivative (TK21) from Streptomyces lividans 66 has been cloned as an autonomously replicating minichromosome (pSOR1) by using the thiostrepton resistance gene as a selectable marker. pSOR1 could be recovered as a closed circular plasmid which shows high segregational instability. pSOR1 was shown to replicate in Streptomyces coelicolor A3(2) and in S. lividans 66 and hybridized with DNA from several different Streptomyces strains. Physical mapping revealed that oriC is located on a 330-kb AseI fragment of the S. coelicolor A3(2) chromosome. DNA sequence analyses showed that the cloned chromosomal oriC region contains numerous DnaA boxes which are arranged in two clusters. The preferred sequence identified in the oriC region of Escherichia coli and several other bacteria is TTATCCACA. In contrast, in S. lividans, which has a high GC content, the preferred sequence for DnaA boxes appears to be TTGTCCACA.     

Short tetracysteine tags to beta-tubulin demonstrate the significance of small labels for live cell imaging

Genetically encoded tags are of fundamental importance for live cell imaging. We show that small tetracysteine (TetCys) tags can be highly advantageous for the functionality of the host protein compared with large fluorescent protein tags. One to three concatenated small TetCys tags as well as the large green fluorescent protein (GFP) were fused by integrative epitope tagging to the C terminus of beta-tubulin (Tub2) in the budding yeast Saccharomyces cerevisiae. The increasing tag size correlated with functional interference to the host protein. Tub2 tagged with either 1 x TetCys (10 amino acids [aa]) or 2 x TetCys (20 aa) was able to substitute Tub2 in haploid cells. In contrast, C-terminal tagging of Tub2 with 3 x TetCys (29 aa) or with GFP (244 aa) resulted in nonviable haploid cells. Cells expressing Tub2-1 x TetCys or Tub2-2 x TetCys were stained with FlAsH, which selectively binds to the TetCys-tag. The stained cells displayed dynamic FlAsH-labeled microtubules and low cellular background fluorescence. The presented approach to tag open reading frames (ORFs) at their native loci with very small TetCys-tags and the subsequent visualization of the tagged proteins in vivo can be extended in principle to any ORF in S. cerevisiae.     

Conversion of Kepone by Methanosarcina thermophila

Abstract Amino acid sequences of protease inhibitors ( Streptomyces subtilisin inhibitor-like proteins) widely distributed in Streptomyces were compared to clarify the taxonomic status of three strains of Streptomyces spp., S. coelicolor A3(2), S. lividans 66 and S. coelicolor Müller, which are closely related by conventional taxonomical procedures. The sequence comparison indicated that S. coelicolor A3(2) is distinct from the type strain S. coelicolor Müller, but belongs to the same taxon as S. lividans 66.     

Expression of a Phytophthora sojae necrosis-inducing protein occurs during transition from biotrophy to necrotrophy

Phytophthora sojae is an oomycete that causes stem and root rot on soybean plants. To discover pathogen factors that produce disease symptoms or activate plant defense responses, we identified putative secretory proteins from expressed sequence tags (ESTs) and tested selected candidates using a heterologous expression assay. From an analysis of 3035 ESTs originating from mycelium, zoospore, and infected soybean tissues, we identified 176 putative secreted proteins. A total of 16 different cDNAs predicted to encode secreted proteins ranging in size from 6 to 26 kDa were selected for expression analysis in Nicotiana benthamiana using an Agrobacterium tumefaciens binary potato virus X (PVX) vector. This resulted in the identification of a 25.6-kDa necrosis-inducing protein that is similar in sequence to other proteins from eukaryotic and prokaryotic species. The genomic region encoding the P. sojae necrosis-inducing protein was isolated and the expression pattern of the corresponding gene determined by RNA blot hybridization and by RT-PCR. The activity of this P. sojae protein was compared to proteins of similar sequence from Fusarium oxysporum, Bacillus halodurans, and Streptomyces coelicolor by PVX-based expression in N. benthamiana and by transient expression via particle bombardment in soybean tissues. The P. sojae protein was a powerful inducer of necrosis and cell death in both assays, whereas related proteins from other species varied in their activity. This study suggests that the P. sojae necrosis-inducing protein facilitates the colonization of host tissues during the necrotrophic phase of growth.     

New Tags for Recombinant Protein Detection and O-Glycosylation Reporters

Monoclonal antibodies (mAbs), because of their unique specificity, are irreplaceable tools for scientific research. Precise mapping of the antigenic determinants allows the development of epitope tagging approaches to be used with recombinant proteins for several purposes. Here we describe a new family of tags derived from the epitope recognized by a single highly specific mAb (anti-roTag mAb), which was obtained from a pool of mAbs reacting with the rotavirus nonstructural protein 5 (NSP5). The variable regions of the anti-roTag mAb were identified and their binding capacity verified upon expression as a single-chain/miniAb. The minimal epitope, termed roTag, was identified as a 10 amino acid sequence (SISSSIFKNE). The affinity of the anti-roTag/roTag interaction was found to be comparable to that of the anti-SV5/SV5 tag interaction. roTag was successfully used for detection of several recombinant cytosolic, secretory and membrane proteins. Two additional variants of roTag of 10 and 13 amino acids containing O-glycosylation susceptible sites (termed OG-tag and roTagO) were constructed and characterised. These tags were useful to detect proteins passing through the Golgi apparatus, the site of O-glycosylation.