Cloning and expression of the secA gene of a marine bacterium,Vibrio alginolyticus,and analysis of its function in Escherichia coli

We report the cloning, sequencing and functional characterization of the secA gene of a marine bacterium, Vibrio alginolyticus, which has been suggested to utilize ATP and the sodium motive force for protein translocation. Oligodeoxynucleotides corresponding to highly conserved regions of Escherichia coli secA located in the high affinity ATP binding site were utilized as PCR primers to clone the secA gene of V. alginolyticus. It was shown to encode a 103.3-kDa protein. The deduced amino acid sequence of V. alginolyticus SecA (VaSecA) exhibits a high degree of identity (72.7%) to SecA of E. coli (EcSecA). The secA gene of E. coli forms an operon with upstream orfX, whereas no counterpart is present upstream of V. alginolyticus secA. Azide derepresses the EcSecA translation, whereas the level of VaSecA was unaffected by azide. Expression of VaSecA in E. coli carrying a temperature-sensitive secA mutation restored both growth and protein translocation at a non-permissive temperature. VaSecA was thus able to substitute for EcSecA despite the fact that the energy requirement for protein translocation differs between the two organisms. VaSecA was overproduced in V. alginolyticus and purified to homogeneity for N-terminal sequencing. The endogenous ATPase activity of the purified VaSecA was comparable with that of EcSecA.     

Regulation of Escherichia coli secA by Cellular Protein Secretion Proficiency Requires an Intact Gene X Signal Sequence and an Active Translocon

secA is translationally regulated by the protein secretion proficiency state of the Escherichia coli cell. This regulation was explored by making signal sequence mutations in the gene upstream of secA, gene X, which promotes secA translational coupling. Gene X signal sequence mutants were constitutive for secA expression, while prlA alleles partially restored secA regulation. These results show that interaction of the pre-gene X protein with the translocon is required for proper secA regulation. Furthermore, gene X signal sequence mutations disrupted secA regulation only in the cis configuration. We propose that nascent pre-gene X protein interacts with the translocon during its secretion to constitute the secretion sensor.     

Characterization of the Nuclear- and Plastid-Encoded secA-Homologous Genes in the Unicellular Red Alga Cyanidioschyzon merolae

SecA is an ATP-driven motor for protein translocation in bacteria and plants. Mycobacteria and listeria were recently found to possess two functionally distinct secA genes. In this study, we found that Cyanidioschyzon merolae, a unicellular red alga, possessed two distinct secA-homologous genes; one encoded in the cell nucleus and the other in the plastid genome. We found that the plastid-encoded SecA homolog showed significant ATPase activity at low temperature, and that the ATPase activity of the nuclear-encoded SecA homolog showed significant activity at high temperature. We propose that the two SecA homologs play different roles in protein translocation.     

Regulation of the Escherichia coli secA Gene Is Mediated by Two Distinct RNA Structural Conformations

Expression from the secA gene, encoding a key component of the general secretory pathway of Escherichia coli, is influenced by the secretion status of the cell, autogenous translational repression, and translational coupling to the upstream gene, X. SecA binds to its mRNA in a region overlapping its ribosome binding site, thus competing with ribosomes that would initiate secA translation. Mapping of the geneX-secA mRNA secondary structure has demonstrated that the RNA can adopt two distinct conformations in solution. The first conformation arises from the base-pairing of the secA Shine-Dalgarno (SD) sequence with the geneX terminus. The second conformation, in which the secA SD sequence is no longer paired with the geneX terminus, contains a GC-rich stem upstream of the secA SD sequence. The presence of this GC-rich stem is supported by structure mapping of a mutant RNA containing a deletion in the geneX terminus. The former structure appears to be involved in translational coupling by directly linking the geneX and secA sequences, where geneX translation activates secA translational initiation through the unpairing and unmasking of the secA SD sequence. As indicated by SecA-RNA binding assays, the latter structure is probably involved in SecA binding and translational repression of the secA gene. The stabilizing effect of magnesium ions toward occlusion of the secA SD sequence supports the presence of RNA tertiary structure in this regulatory domain. Received: 30 July 1998 / Accepted: 18 September 1998     

High-Temperature Ethanol Fermentation and Transformation with Linear DNA in the Thermotolerant Yeast Kluyveromyces marxianus DMKU3-1042

We demonstrate herein the ability of Kluyveromyces marxianus to be an efficient ethanol producer and host for expressing heterologous proteins as an alternative to Saccharomyces cerevisiae. Growth and ethanol production by strains of K. marxianus and S. cerevisiae were compared under the same conditions. K. marxianus DMKU3-1042 was found to be the most suitable strain for high-temperature growth and ethanol production at 45°C. This strain, but not S. cerevisiae, utilized cellobiose, xylose, xylitol, arabinose, glycerol, and lactose. To develop a K. marxianus DMKU3-1042 derivative strain suitable for genetic engineering, a uracil auxotroph was isolated and transformed with a linear DNA of the S. cerevisiae ScURA3 gene. Surprisingly, Ura⁺ transformants were easily obtained. By Southern blot hybridization, the linear ScURA3 DNA was found to have inserted randomly into the K. marxianus genome. Sequencing of one Lys⁻ transformant confirmed the disruption of the KmLYS1 gene by the ScURA3 insertion. A PCR-amplified linear DNA lacking K. marxianus sequences but containing an Aspergillus α-amylase gene under the control of the ScTDH3 promoter together with an ScURA3 marker was subsequently used to transform K. marxianus DMKU3-1042 in order to obtain transformants expressing Aspergillus α-amylase. Our results demonstrate that K. marxianus DMKU3-1042 can be an alternative cost-effective bioethanol producer and a host for transformation with linear DNA by use of S. cerevisiae-based molecular genetic tools.     

Molecular identification of ‘Candidatus Phytoplasma palmicola’ associated with coconut lethal yellowing in Equatorial Guinea

During the past two decades, a high mortality of coconut palms was observed in the coastal areas of Equatorial Guinea. Reportedly, the palm population has been reduced by 60%–70%, and coconut production has decreased accordingly. To identify the cause of the mortality, a survey was carried out in April 2021 in various localities of the coconut belt. Molecular analyses carried out on 16S rRNA and secA genes detected phytoplasma presence in the majority of the samples. Sequencing and BLAST search of the 16S rRNA gene sequences showed >99% identity of the detected phytoplasmas to ‘Candidatus Phytoplasma palmicola’. The RFLP analyses of 16S ribosomal gene using Tru1I and TaqI enzymes led to assign these phytoplasmas to subgroup 16SrXXII-A. In all samples that tested positive, including one from a hybrid coconut palm and two from oil palm the same phytoplasma was identified. The phylogenetic analyses of 16S rRNA and secA genes confirmed respectively 99.98%–100% and 97.94%–100% identity to ‘Ca. P. palmicola’. RFLP analyses using MboII enzyme on the secA gene amplicon differentiated the phytoplasma found in Equatorial Guinea from those present in Ghana and Ivory Coast. The Equatorial Guinean phytoplasma strain resulted to be identical to the strains from Mozambique, confirming the presence of a geographic differentiation among phytoplasma strains in the coastal areas of Western and Central Africa. The identified phytoplasma is different from the ‘Ca. P. palmicola’ strains found in Ghana and Ivory Coast and represents the first identification a 16SrXXII-A strain in Equatorial Guinea and in Central Africa. Strict monitoring and surveillance procedures for early detection of the pathogen are strongly recommended to reduce its impact and further spread in the country and permit the recovery of coconut plantations.     

Expression of 2S Seed Storage Protein Gene of Brassica juncea in Transgenic Tobacco Plants under Constitutive and Seed-specific Promoters

The coding and upstream promoter regions of Brassica juncea 2S seed storage protein gene were amplified by polymerase chain reaction. The plant expression cassettes containing 2S seed storage protein gene under the control of either a constitutive Caulimovirus 35S promoter or a seed specific 2S protein promoter and the polyadenylation signal of a pea rbcS gene were used for Agrobacterium — mediated transformation of tobacco (Nicotiana tabacum cv Petit Havana). Integration of 2S gene was confirmed by Southern blot and PCR analysis of plant genomic DNA. Expression of introduced 2S protein gene was monitored by slot blot analysis of total RNA using 2S protein sequence as hybridization probe and also by immunodot blot analysis using specific antiserum of 2S protein. Expression was either constitutive with CaMV 35S promoter or highly seed-specific with Brassica 2S promoter.     

Genome Wide Analysis for Searching Novel Markers to Rapidly Identify Clostridium Strains

Microbial classification is based largely on the 16S rRNA (rrs) gene sequence, which is conserved throughout the prokaryotic domain. The Ribosomal Database Project (RDP) has become a reference point for almost all practical purposes. The use of this gene is limited by the fact that it can be used to identify only to the extent to what has been known and is available in the RDP. In order to identify an organism whose rrs is not present in the RDP database, we need to generate novel markers to place the unknown on the evolutionary map. Here, sequenced genomes of 27 Clostridium strains belonging to 9 species have been used to identify two sets of genes: (1) common to most of the species, and (2) unique to a species. Combinations of genes (recN, dnaJ, secA, mutS, and/or grpE) and their unique restriction endonuclease digestion (AluI, BfaI and/or Tru9I) patterns have been established to rapidly identify Clostridium species. This strategy for identifying novel markers can be extended to all other organisms and diagnostic applications.

Electronic supplementary material

The online version of this article (doi:10.1007/s12088-015-0535-7) contains supplementary material, which is available to authorized users.     

The Development of Monoclonal Antibodies to the secA Protein of Cape St. Paul Wilt Disease Phytoplasma and Their Evaluation as a Diagnostic Tool

Partial recombinant secA proteins were produced from six different phytoplasma isolates representing five 16Sr groups and the expressed, purified recombinant (partial secA) protein from Cape St. Paul wilt disease phytoplasma (CSPWD, 16SrXXII) was used to immunise mice. Monoclonal antibodies (mAbs) were selected by screening hybridoma supernatants for binding to the recombinant proteins. To characterise the binding to proteins from different phytoplasmas, the antibodies were screened by ELISA and western blotting, and epitope mapping was undertaken. Eight different mAbs with varying degrees of specificity against recombinant proteins from different phytoplasma groups were selected. Western blotting revealed that the mAbs bind to proteins in infected plant material, two of which were specific for phytoplasmas. ELISA testing of infected material, however, gave negative results suggesting that either secA was not expressed at sufficiently high levels, or conformational changes of the reagents adversely affected detection. This work has shown that the phytoplasma secA gene is not a suitable antibody target for routine detection, but has illustrated proof of principle for the methodology.     

Molecular typing of Coorg black pepper yellows phytoplasma by multiple gene analyses

In previous work, Coorg black pepper yellows phytoplasma (CBPYp), a ‘Candidatus Phytoplasma asteris'‐related strain, was identified in association with black pepper plants exhibiting yellows symptoms in southern India. In the present study, multiple gene (16S rRNA, tuf, rplV‐rpsC, secY and secA) sequence analyses were carried out for finer characterisation of CBPYp isolates identified in seven plants. Nucleotide sequences of each gene studied were identical among all the CBPYp isolates here analysed. Comparison of virtual restriction fragment length polymorphism (RFLP) patterns, validated by actual digestion of polymerase chain reaction (PCR) products, revealed that CBPYp is a member of subgroups 16SrI‐B, rpI‐L, tufI‐B, secYI‐L and secA1‐A. Interestingly, alignments of nucleotide sequences with other ‘Candidatus Phytoplasma asteris'‐related strains revealed the presence of CBPYp‐specific single nucleotide polymorphisms (SNPs), located in restriction sites for endonucleases not used for conventional classification. CBPYp‐specific SNPs in genes 16S rRNA, tuf and secA were detectable by virtual and actual RFLP assays, while SNPs present in rplV‐rpsC and secY genes were not located in any restriction recognition site. CBPYp‐specific SNPs can be used as molecular markers for the specific identification of CBPYp and for future research focused on investigating epidemiology and ecology of CBPYp in India.     

Lentivirus-mediated RNAi knockdown of LMP2A inhibits the growth of nasopharyngeal carcinoma cell line C666-1 in vitro

Latent membrane protein 2A (LMP2A) is found to play a key role in the development of nasopharyngeal carcinoma (NPC). However, the role of LMP2A silencing in the inhibition of cell growth of NPC has not been clarified. In this study, we inhibited LMP2A gene expression by lentivirus-mediated RNAi, to explore the effects of LMP2A silencing on the growth of NPC cell line in vitro. A lentivirus-mediated RNAi technology was employed to specifically knock down the LMP2A gene in NPC cell line C666-1. Quantitative real-time polymerase chain reaction, Western blot, flow cytometry and colony formation assays were performed to evaluate the expression of LMP2A and biological behavior of cell line C666-1 in vitro. We successfully construct a highly efficient and stable lentivirus vector, which efficiently downregulate the expression of LMP2A gene in infected cell line C666-1. Down-regulation of the expression of LMP2A significantly inhibits the proliferation and colony formation of C666-1 cells. In addition, the specific down-regulation of LMP2A arrests cells in G0/G1 phase of cell cycle and increases apoptosis rate. Our findings suggest that lentivirus-mediated RNAi knockdown of LMP2A inhibits the growth of NPC cell line C666-1 in vitro, and LMP2A may be a potential target for gene therapy in treatment of NPC.     

大肠杆菌突变株高密度生长的多因素分析

【背景】pBHR68是表达聚-3-羟基丁酸酯(Poly-3-Hydroxybutyrate,PHB)合成基因簇的高拷贝质粒,大肠杆菌K-12突变菌株S17-3在携带该质粒时生长密度高,耐低p H且在低pH条件下生长时高产可拉酸(Colanic Acid,CA)。【目的】系统探究与菌种(大肠杆菌S17-3)及质粒(pBHR68)相关的高密度生长现象的分子机理,提示PHB和CA合成代谢与高密度生长的偶联机制。【方法】解析质粒的构成、CA合成途径基因组成对高密度生长现象的影响;利用全基因组同比分析寻找可能的关键突变基因;开展转录组学分析,筛查大肠杆菌S17-3及其转化子在不同培养方式中的转录组数据,通过基因敲除实现基因功能及细胞生长状态的验证。【结果】大肠杆菌S17-3的高密度生长菌与PHB合成的操纵子的过表达以及rhsA的多位点突变相关,RcsA是CA合成与高密度生长中碳代谢流调控的关键调控蛋白。在低pH培养时,敲除可拉酸合成的关键糖基转移酶导致生物量提升;此外,大肠杆菌S17-3/pBHR68的高密度生长还可能与乳糖操纵子异常的转录调控相关,lacZ突变株高密度生长特性消失,而且无法合成可拉酸。【结论】研究分析了引起大肠杆菌S17-3高密度生长的多种因素,为大肠杆菌提高生长密度现象的进一步分析提供了重要线索,也为利用大肠杆菌S17-3的优异生理特性将其改造为寡糖合成的底盘细胞奠定了研究基础。     

Classification of a new phytoplasmas subgroup 16SrII-W associated with <Emphasis Type="Italic">Crotalaria</Emphasis> witches’ broom diseases in Oman based on multigene sequence analysis

Background

Crotalaria aegyptiaca, a low shrub is commonly observed in the sandy soils of wadis desert and is found throughout all regions in Oman. A survey for phytoplasma diseases was conducted. During a survey in a wild area in the northern regions of Oman in 2015, typical symptoms of phytoplasma infection were observed on C. aegyptiaca plants. The infected plants showed an excessive proliferation of their shoots and small leaves.

Results

The presence of phytoplasma in the phloem tissue of symptomatic C. aegyptiaca leaf samples was confirmed by using Transmission Electron Microscopy (TEM). In addition the extracted DNA from symptomatic C. aegyptiaca leaf samples and Orosius sp. leafhoppers were tested by PCR using phytoplasma specific primers for the 16S rDNA, secA, tuf and imp, and SAP11 genes. The PCR amplifications from all samples yielded the expected products, but not from asymptomatic plant samples. Sequence similarity and phylogenetic tree analyses of four genes (16S rDNA, secA, tuf and imp) showed that Crotalaria witches’ broom phytoplasmas from Oman is placed with the clade of Peanut WB (16SrII) close to Fava bean phyllody (16SrII-C), Cotton phyllody and phytoplasmas (16SrII-F), and Candidatus Phytoplasma aurantifolia’ (16SrII-B). However, the Crotalaria’s phytoplasma was in a separate sub-clade from all the other phytoplasmas belonging to Peanut WB group. The combination of specific primers for the SAP11 gene of 16SrII-A, ?B, and -D subgroup pytoplasmas were tested against Crotalaria witches’ broom phytoplasmas and no PCR product was amplified, which suggests that the SAP11 of Crotalaria phytoplasma is different from the SAP11 of the other phytoplasmas.

Conclusion

We propose to assign the Crotalaria witches’ broom from Oman in a new lineage 16SrII-W subgroup depending on the sequences analysis of 16S rRNA, secA, imp, tuf, and SAP11 genes. To our knowledge, this is the first report of phytoplasmas of the 16SrII group infecting C. aegyptiaca worldwide.

     

Molecular cloning and nucleotide sequence of Streptomyces griseus trypsin gene.

Streptomyces griseus trypsin (E.C. 3.4.21.4) is one of the major extracellular proteinase, which is secreted by S. griseus. The gene encoding S. griseus trypsin was isolated from a S. griseus genomic library by using a synthetic oligonucleotide probe. Fragments containing the gene for S. griseus trypsin were characterized by hybridization and demonstration of proteolytic activity in S. lividans. Deduced amino acid sequence from the nucleotide sequence suggests that S. griseus trypsin is produced as a precursor, consisting of three portions; an amino-terminal pre sequence (32 amino acid residues), a pro sequence (4 residues), and the mature trypsin. The S. griseus trypsin consists of 223 amino acids with a computed molecular weight of 23,112. The existence of proline at the pro and mature junction suggests that the processing of S. griseus trypsin is non-autocatalytic.     

The use of extragenic suppressors to define genes involved in protein export in Escherichia coli

Summary The secA gene codes for a membrane component involved in protein export in E. coli. In order to define other genes whose products play such a role, we have characterized extragenic suppressors of a secA(Ts) mutation. These suppressors fall into at least three genetic loci. One such locus is the prlA gene, previously identified by mutations which suppress signal sequence mutants. Thus, this approach may allow the identification of new genes involved in the export process.     

Genetic analysis and molecular mapping of a stripe rust resistance gene derived from Psathynrostachys huashanica Keng in wheat line H9014-121-5-5-9

Stripe rust, caused by Puccinia striiformis f. sp. tritici (Pst), is one of the most devastating diseases worldwide and is also an important disease in China. The wheat translocation line H9014-121-5-5-9 was originally developed from interspecific hybridization between wheat (Triticum aestivum L.) line 7182 and Psathyrostachys huashanica Keng. This translocation line showed resistance to predominant stripe rust races in China when it was tested with nine races of Pst. To determine the inheritance and map the resistance gene, segregating populations were developed from the cross between H9014-121-5-5-9 and the susceptible cultivar Mingxian 169. The seedlings of the F1, F2, and F2:3 generations were tested with race CYR31. The results showed that the resistance in H9014-121-5-5-9 was conferred by a single dominant gene. Bulked segregant analysis and simple sequence repeat (SSR) markers were used to identify polymorphic markers associated with the resistance gene locus. Seven polymorphic SSR markers were linked to the resistance gene. A linkage map was constructed according to the genotypes of the seven SSR markers and the resistance gene. Based on the SSR marker positions on the wheat chromosome, the resistance gene was assigned on chromosome 1AL, temporarily designated YrHA. Based on chromosomal location, reaction patterns and pedigree analysis, YrHA should be a novel resistance gene to stripe rust. The molecular markers of the new resistance gene in H9014-121-5-5-9 could be useful for marker-assisted selection in breeding programs against stripe rust.