The 5′-UTR intron of the midgut-specific BmAPN4 gene affects the level and location of expression in transgenic silkworms

Introns are important for regulating gene expression. BmAPN4, which has a 5′-UTR upstream intron (5UI), is specifically expressed in the entire silkworm midgut. In our previous study, the promoter region upstream of the 5UI of BmAPN4 was cloned and identified as the P3 promoter (P3P) with activity only in the anterior midgut. In this study, the sequence consisting of the P3P and the 5UI was cloned and named as P3P+5UI. A transgenic vector was constructed in which EGFP was controlled by P3P+5UI. Transgenic P3+5UI silkworms were generated by embryo microinjection. RT-PCR showed P3P+5UI activity throughout the larval stage. Intense green fluorescence was seen only in the entire midgut of P3+5UI silkworms and expression was confirmed by RT-PCR. qPCR revealed that expression of EGFP in the anterior midgut of P3+5UI silkworms was 64% higher than in P3 silkworms, indicating the 5UI sustained intron-mediated enhancement of gene expression. These results suggested that the BmAPN4 5UI affected the level and site of expression. The 5UI was cloned and added behind P2P, another specific promoter with activity only in the anterior midgut of silkworm, to construct the P2P+5UI and transgenic P2+5UI silkworms. Expression patterns were the same for P2P+5UI and P2P, suggesting that the 5UI of BmAPN4 did not affect P2P. This study found that the BmAPN4 5UI affected the amount and location of gene expression. Its influence appeared to be dependent on a specific promoter.     

Inhibition of the synthesis of polyamines and macromolecules by 5′-methylthioadenosine and 5′-alkylthiotubercidins in BHK21 cells

5′-Methylthioadenosine and four 5′-alkylthiotubercidins were tested for their ability to inhibit polyamine synthesis in vitro and to decrease polyamine concentration and prevent growth of baby-hamster-kidney (BHK21) cells. 5′-Methylthioadenosine and 5′-methylthiotubercidin decreased the activity of spermidine synthase from brain to roughly the same extent, whereas brain spermine synthase was much more strongly inhibited by 5′-methylthioadenosine compared with 5′-methylthiotubercidin. These nucleoside derivatives also inhibited the growth of BHK21 cells and increased the concentration of putrescine. 5′-Methylthioadenosine decreased cellular spermine concentration, whereas 5′-methylthiotubercidin lowered the concentration of spermidine. The activities of ornithine decarboxylase and S-adenosylmethionine decarboxylase were enhanced in cells grown in the presence of 5′-methylthiotubercidin. The growth inhibition produced by these nucleoside derivatives was not reversed by exogenous spermidine or spermine. 5′-Ethylthiotubercidin, 5′-propylthiotubercidin and 5′-isopropylthiotubercidin did not appreciably inhibit spermidine or spermine synthase in vitro or decrease the cellular polyamine content, but effectively prevented the growth of BHK21 cells. All nucleoside derivatives at concentrations of 0.2–1 mm caused a rapid inhibition of protein synthesis. It is concluded that the growth inhibition produced by 5′-methylthioadenosine and 5′-alkylthiotubercidins was not primarily due to polyamine depletion but other target sites, for instance the cellular nucleotide pool, cell membranes etc. must be considered.     

Apical and lateral shoot apex-specific expression is conferred by promoter of the seed storage protein β-phaseolin gene

A previous analysis with deletion mutants of the native -phaseolin gene demonstrated that removal of a negative element 5 upstream of–107 permitted phaseolin expression in stem cortex and secondary root (Burowet al., 1992). Here we employed the -glucuronidase (GUS) reporter gene to visualize, by histochemical staining, the cell type-specificity of phaseolin expression in stem and root, and to understand further the spatial control of the -phaseolin gene. The 782 bp 5 upstream promoter and its deletion mutants were fused to the GUS gene, and these chimaeric genes were used to transform tobacco. Histochemical staining for GUS activity demonstrated that phaseolin promoters truncated downstream of –227 conferred cell-type specific expression in internal/external phloem and protoxylem of mature stem. Surprisingly, GUS staining was prominent in both apical and lateral shoot apices of plants that contain the full-length –782 promoter and mutant promoters deleted up to –64. GUS expression was extended to all cell types of shoot tips, including epidermis, cortex, vasculature, procambium and pith. Expression in vasculature of petioles was limited to plants with promoters truncated to –106 and –64. The current results are in agreement with our previous findings with the native phaseolin gene: that the major positive element (–295/–228) is sufficient for seed-specific late-temporal expression of the phaseolin gene. We conclude that the 5 upstream sequence of the -phaseolin gene directs spatially- and temporally-controlled gene expression in developing seeds during the reproductive phase, but also confers expression in shoot apices during the vegetative phase of plant development.     

Regulation of zinc-responsive Slc39a5 (Zip5) translation is mediated by conserved elements in the 3′-untranslated region

Translation of the basolateral zinc transporter ZIP5 is repressed during zinc deficiency but Zip5 mRNA remains associated with polysomes and can be rapidly translated when zinc is repleted. Herein, we examined the mechanisms regulating translation of Zip5. The 3′-untranslated region (UTR) of Zip5 mRNA is well conserved among mammals and is predicted by mFOLD to form a very stable stem-loop structure. Three algorithms predict this structure to be flanked by repeated seed sites for miR-328 and miR-193a. RNAse footprinting supports the notion that a stable stem-loop structure exists in this 3′-UTR and electrophoretic mobility shift assays detect polysomal protein(s) binding specifically to the stem-loop structure in the Zip5 3′-UTR. miR-328 and miR-193a are expressed in tissues known to regulate Zip5 mRNA translation in response to zinc availability and both are polysome-associated consistent with Zip5 mRNA localization. Transient transfection assays using native and mutant Zip5 3′-UTRs cloned 3′ to luciferase cDNA revealed that the miRNA seed sites and the stem-loop function together to augment translation of Zip5 mRNA when zinc is replete.     

Chaperone-aided expression of LipA and LplA followed by the increase in α-lipoic acid production

α-Lipoic acid (LA), a naturally occurring cofactor reported to be present in a diverse group of microorganisms, plants, and animal tissues, has been widely and successfully used as a therapy for a variety of diseases, including diabetes and heart disease. However, to date, recombinant DNA technology has not been applied for higher LA production due mainly to difficulties in the functional expression of key enzymes involved in LA production. Here, we report a study for higher LA production with the aid of chaperone plasmids, DnaKJE and trigger factor (Tf). The lipA and lplA genes encoding lipoate synthase and lipoate protein ligase in Pseudomonas fluorescens, respectively, were cloned and transformed into Escherichia coli K12. When they were overexpressed in E. coli, both LipA and LplA were expressed as inclusion bodies leading to no increase in LA production. However, when chaperone plasmids DnaKJE and Tf were coexpressed with lipA and lplA, the resulting recombinant E. coli strains showed higher LA production than the wild-type E. coli by 32–111%, respectively.     

Identification of the substrate recognition region in the Δ6-fatty acid and Δ8-sphingolipid desaturase by fusion mutagenesis

Δ⁸-sphingolipid desaturase and Δ⁶-fatty acid desaturase share high protein sequence identity. Thus, it has been hypothesized that Δ⁶-fatty acid desaturase is derived from Δ⁸-sphingolipid desaturase; however, there is no direct proof. The substrate recognition regions of Δ⁶-fatty acid desaturase and Δ⁸-sphingolipid desaturase, which aid in understanding the evolution of these two enzymes, have not been reported. A blackcurrant Δ⁶-fatty acid desaturase and a Δ⁸-sphingolipid desaturase gene, RnD6C and RnD8A, respectively, share more than 80 % identity in their coding protein sequences. In this study, a set of fusion genes of RnD6C and RnD8A were constructed and expressed in yeast. The Δ⁶- and Δ⁸-desaturase activities of the fusion proteins were characterized. Our results indicated that (1) the exchange of the C-terminal 172 amino acid residues can lead to a significant decrease in both desaturase activities; (2) amino acid residues 114–174, 206–257, and 258–276 played important roles in Δ⁶-substrate recognition, and the last two regions were crucial for Δ⁸-substrate recognition; and (3) amino acid residues 114–276 of Δ⁶-fatty acid desaturase contained the substrate recognition site(s) responsible for discrimination between ceramide (a substrate of Δ⁸-sphingolipid desaturase) and acyl-PC (a substrate of Δ⁶-fatty acid desaturase). Substituting the amino acid residues 114-276 of RnD8A with those of RnD6C resulted in a gain of Δ⁶-desaturase activity in the fusion protein but a loss in Δ⁸-sphingolipid desaturase activity. In conclusion, several regions important for the substrate recognition of Δ8-sphingolipid desaturase and Δ⁶-fatty acid desaturase were identified, which provide clues in understanding the relationship between the structure and function in desaturases.     

GUS expression in Arabidopsis directed by 5′ regions of the pea metallothionein-like gene PsMT A

Upstream sequences (including the first seven codons) of a metallothionein (MT)-like gene from pea, PsMT A, were fused to GUS and introduced into Arabidopsis. High-level GUS expression was detected in the roots of plants grown on MS medium, except in regions proximal to the root apex. There was precise delineation of the root-shoot boundary. In soil-grown plants there was low GUS expression and this was absent from the more mature regions of the roots. In the aerial tissues of soil-grown plants, GUS expression was restricted to hydathodes, stipules, expanding cotyledons and the following senescent tissues: leaves, cotyledons, petals, sepals, filaments, stigmas, nectaries and siliques. A 298 bp region was shown to be required for GUS expression in roots but not for expression in vegetative aerial tissues of plants grown on MS medium. This region contains predicted ethylene-responsive elements (EREs) but similar patterns of GUS expression were detected in etr1 seedlings. GUS expression was significantly higher in roots exposed to 500 nM copper, but this increase was small in proportion to expression in roots exposed to 50 nM copper.     

High efficiency plastid transformation in potato and regulation of transgene expression in leaves and tubers by alternative 5′ and 3′ regulatory sequences

Transformation of potato plastids is limited by low transformation frequencies and low transgene expression in tubers. In order to improve the transformation efficiency, we modified the regeneration procedure and prepared novel vectors containing potato flanking sequences for transgene integration by homologous recombination in the Large Single Copy region of the plastome. Vector delivery was performed by the biolistic approach. By using the improved regeneration procedure and the potato flanking sequences, we regenerated about one shoot every bombardment. This efficiency corresponds to 15–18-fold improvement compared to previous results with potato and is comparable to that usually achieved with tobacco. Further, we tested five promoters and terminators, and four 5′-UTRs, to increase the expression of the gfp transgene in tubers. In leaves, accumulation of GFP to about 4% of total soluble protein (TSP) was obtained with the strong promoter of the rrn operon, a synthetic rbcL-derived 5′-UTR and the bacterial rrnB terminator. GFP protein was detected in tubers of plants transformed with only four constructs out of eleven. Best results (up to approximately 0.02% TSP) were achieved with the rrn promoter and rbcL 5′-UTR construct, described above, and another containing the same terminator, but with the promoter and 5′-UTR from the plastid clpP gene. The results obtained suggest the potential use of clpP as source of novel regulatory sequences in constructs aiming to express transgenes in amyloplasts and other non-green plastids. Furthermore, they represent a significant advancement of the plastid transformation technology in potato, of relevance to its implementation in potato breeding and biotechnology.     

Identification, expression and tissue distribution of cytidine 5′-monophosphate N-acetylneuraminic acid synthetase activity in the rat

We report the postnatal developmental profiles of N-acetylneuraminic acid cytidylyltransferase (EC 2.7.7.43) (CMP-Neu5Ac synthetase) in different rat tissues. This enzyme, which catalyses the activation of NeuAc to CMP-Neu5Ac, was detected in brain, kidney, heart, spleen, liver, stomach, intestine, lung, thymus, prostate and urinary bladder but not in skeletal muscle. Comparative analysis of the different specific activity profiles obtained shows that the expression of CMP Neu5Ac synthetase is tissue-dependent and does not seem to be embryologically determined. Changes in the level of sialylation during development were also found to be intimately related to variations in the expression of this enzyme, at least in brain, heart, kidney, stomach, intestine and lung.