Vector design for optimal protein expression

Many DNA constructs are generated for protein expression studies. Translational properties and mRNA stability are crucial aspects that have to be accounted for during DNA construction. An optimized vector for protein overexpression studies is described considering elements in the mature mRNA that influence translatability and stability. Recommendations regarding vector construction for Xenopus laevis embryo injection are provided, based on literature and experimental data. The 5'untranslated region (5'UTR) should be non-regulated, short, unstructured, and without AUG codons. The sequence around the start codon should match the initiation context of the species studied (ACCAUGG, for vertebrates), and the open reading frame should be cloned with its own stop codon, followed by a G or A residue. Furthermore, the 3'UTR should be non-regulated, and a strong polyadenylation signal must be included in DNA vectors. In RNA template vectors, the presence of a poly(A) or AC tail is essential for stability, as well as for translation efficiency in mRNA injection experiments. These aspects result in high-level expression of exactly the desired protein. Easily obtainable examples of the sequences [5'UTR, 3'UTR, and poly(A) signal] are suggested.     

Regulation of rat ornithine decarboxylase mRNA translation by its 5'-untranslated region

Ornithine decarboxylase (ODC), a key enzyme in polyamine biosynthesis, is a highly inducible protein whose expression involves a complex and variable array of regulatory mechanisms. We investigated the influence of the 5'-untranslated region (5'UTR) of the rat ODC mRNA on translation of the mRNA in a cell-free system and in cultured mammalian cells. ODC mRNA containing the full-length 5'UTR was translated in reticulocyte lysates at approximately 5% of the rate of mRNA containing no ODC 5' leader sequences. The complete 5'UTR inhibited expression of a heterologous gene product, human growth hormone, to the same extent in cultured mammalian cells. Furthermore, the 5'-most 130 bases of the rat ODC 5'UTR, a conserved G/C-rich region predicted to form a stable stem-loop structure (delta G = -68 kcal/mol), repressed translation to the same extent as the entire 5'UTR, both in the lysates and in intact cells. The 3'-most 160 bases of the 5'UTR, containing a small upstream open reading frame, decreased expression by 50-65% both in vitro and in intact cells, compared with controls lacking any ODC 5'UTR sequences. Mutation of the initiation codon AUG beginning this upstream open reading frame to GCG restored expression to rates equivalent to those seen in constructions containing no ODC 5'UTR sequences. We conclude that the rat ODC mRNA 5'UTR can inhibit translation of ODC mRNA both in vitro and in vivo, and that the predicted stem-loop structure at the 5' end of the 5'UTR is both necessary and sufficient for this inhibition.     

Autoregulation of poly(A)-binding protein synthesis in vitro.

The poly(A)-binding protein (PABP), in a complex with the 3'poly(A) tail of eukaryotic mRNAs, plays important roles in the control of translation and message stability. All known examples of PABP mRNAs contain an extensive A-rich sequence in their 5' untranslated regions. Studies in mammalian cells undergoing growth stimulation or terminal differentiation indicate that PABP expression is regulated at the translational level. Here we examine the hypothesis that synthesis of the PABP is autogenously controlled. We show that the endogenous inactive PABP mRNA in rabbit reticulocytes can be specifically stimulated by addition of low concentrations of poly(A) and that this stimulation is also observed with in vitro transcribed human PABP mRNA. By deleting the A-rich region from the leader of human PABP mRNA and adding it upstream of the initiator AUG in a reporter mRNA we show that the adenylate tract is sufficient and necessary for mRNA repression and poly(A)-mediated activation in the reticulocyte cell-free system. UV cross-linking experiments demonstrate that the leader adenylate tract binds PABP. Furthermore, addition of recombinant GST-PABP to the cell-free system represses translation of mRNAs containing the A-rich sequence in their 5'UTR, but has no effect on control mRNA. We thus conclude that in vitro PABP binding to the A-rich sequence in the 5' UTR of PABP mRNA represses its own synthesis.     

A U-rich element in the 5' untranslated region is necessary for the translation of p27 mRNA

Increased translation of p27 mRNA correlates with withdrawal of cells from the cell cycle. This raised the possibility that antimitogenic signals might mediate their effects on p27 expression by altering complexes that formed on p27 mRNA, regulating its translation. In this report, we identify a U-rich sequence in the 5' untranslated region (5'UTR) of p27 mRNA that is necessary for efficient translation in proliferating and nonproliferating cells. We show that a number of factors bind to the 5'UTR in vitro in a manner dependent on the U-rich element, and their availability in the cytosol is controlled in a growth- and cell cycle-dependent fashion. One of these factors is HuR, a protein previously implicated in mRNA stability, transport, and translation. Another is hnRNP C1 and C2, proteins implicated in mRNA processing and the translation of a specific subset of mRNAs expressed in differentiated cells. In lovastatin-treated MDA468 cells, the mobility of the associated hnRNP C1 and C2 proteins changed, and this correlated with increased p27 expression. Together, these data suggest that the U-rich dependent RNP complex on the 5'UTR may regulate the translation of p27 mRNA and may be a target of antimitogenic signals.     

Post-transcriptional regulation of human cathepsin L expression

The expression of cathepsin L, a lysosomal protease, is known to be elevated in cancer and other pathologies. Multiple splice variants of human cathepsin L with variable 5'UTRs exist, which encode for the same protein. Previously we have observed that variant hCATL A (bearing the longest 5'UTR) was translated in vitro with significantly lower efficiency than variant hCATL AIII (bearing the shortest 5'UTR). Contrary to these findings, results of the present study reveal that in cancer cells, hCATL A mRNA exhibits higher translatability in spite of having lower stability than AIII. This is the first report demonstrating a highly contrasting trend in translation efficiencies of hCATL variants in rabbit reticulocytes and live cells. Expression from chimeric mRNAs containing 5'UTRs of A or AIII upstream to luciferase reporter cDNA established the A UTR to be the sole determinant for this effect. Transient transfections of bicistronic plasmids and mRNAs confirmed the presence of a functional Internal Ribosome Entry Site in this UTR. Our data suggest that differential stability and translation initiation modes mediated by the 5'UTRs of human cathepsin L variants are involved in regulating its expression.     

Efficient translation initiation directed by the 900-nucleotide-long and GC-rich 5' untranslated region of the human retrotransposon LINE-1 mRNA is strictly cap dependent rather than internal ribosome entry site mediated

Retrotransposon L1 is a mobile genetic element of the LINE family that is extremely widespread in the mammalian genome. It encodes a dicistronic mRNA, which is exceptionally rare among eukaryotic cellular mRNAs. The extremely long and GC-rich L1 5' untranslated region (5'UTR) directs synthesis of numerous copies of RNA-binding protein ORF1p per mRNA. One could suggest that the 5'UTR of L1 mRNA contained a powerful internal ribosome entry site (IRES) element. Using transfection of cultured cells with the polyadenylated monocistronic (L1 5'UTR-Fluc) or bicistronic (Rluc-L1 5'UTR-Fluc) RNA constructs, capped or uncapped, it has been firmly established that the 5'UTR of L1 does not contain an IRES. Uncapping reduces the initiation activity of the L1 5'UTR to that of background. Moreover, the translation is inhibited by upstream AUG codons in the 5'UTR. Nevertheless, this cap-dependent initiation activity of the L1 5'UTR was unexpectedly high and resembles that of the beta-actin 5'UTR (84 nucleotides long). Strikingly, the deletion of up to 80% of the nucleotide sequence of the L1 5'UTR, with most of its stem loops, does not significantly change its translation initiation efficiency. These data can modify current ideas on mechanisms used by 40S ribosomal subunits to cope with complex 5'UTRs and call into question the conception that every long GC-rich 5'UTR working with a high efficiency has to contain an IRES. Our data also demonstrate that the ORF2 translation initiation is not directed by internal initiation, either. It is very inefficient and presumably based on a reinitiation event.     

Effect of single and repeated methamphetamine treatment on neurotransmitter release in substantia nigra and neostriatum of the rat

There are tissue specific discrepancies in expression of tryptophan hydroxylase (TPH) between the pineal gland and brainstem. TPH mRNA levels in the pineal are much higher than in the brainstem, however, the two tissues contain comparable protein levels. This discrepancy could result from different translation efficiency of two of the TPH mRNA isoforms. Using PCR-based methods, we analyzed the relative expression, in pineal and brainstem, of two TPH mRNA isoforms differing in the length of their untranslated region (5'UTR). The levels of the TPHalpha were found to be 960-fold more abundant than the 51-nucleotide longer TPHbeta, in the pineal. TPHbeta was also detected for the first time in the brainstem, where TPHbeta/TPHalpha was about five-fold higher than in the pineal. To study the role of the different 5'UTRs, each was cloned in-frame upstream of luciferase, and transfected into PC12 cells. Both 5'UTRs enhanced luciferase activity, with TPHbeta 5'UTR being more effective than TPHalpha 5'UTR, indicating selective regulation of translation efficiency. We also examined whether physiological manipulations alter the distribution of the TPH mRNA isoforms. Repeated stress had no effect in pineal, but led to a marked preferential induction of TPHbeta in brainstem. Modulation of TPH gene expression in serotonergic neurons could result from selective and tissue specific regulation of its mRNA isoforms.     

Brain-derived neurotrophic factor expression is repressed during myogenic differentiation by miR-206

Brain-derived neurotrophic factor (BDNF) is required for efficient skeletal-muscle regeneration and perturbing its expression causes abnormalities in the proliferation and differentiation of skeletal muscle cells. In this study, we investigated the mechanism of BDNF suppression that occurs during myogenic differentiation. BDNF is expressed at the mRNA level as two isoforms that differ in the length of their 3'UTRs as a result of alternative cleavage and polyadenylation. Sequence analysis revealed the presence of three miR-206 target sites in the long BDNF 3'UTR (BDNF-L), whereas only one site was found in the short mRNA BDNF 3'UTR (BDNF-S). miR-206 is known to regulate the differentiation of C2C12 myoblasts and its expression is induced during the transition from myoblasts to myotubes. We thus examined whether miR-206-mediated suppression is responsible for the expression pattern of BDNF during myogenic differentiation. BDNF-L was suppressed to a greater extent than BDNF-S during differentiation of C2C12 myoblasts. Transfection of a miR-206 precursor decreased activity of reporters representative of the BDNF-L 3'UTR, but not BDNF-S 3'UTR, and repressed endogenous BDNF mRNA levels. This suppression was found to be dependent on the presence of multiple miR-206 target sites in the BDNF-L 3'UTR. Conversely, suppression of miR-206 levels resulted in de-repression of BDNF 3'UTR reporter activity and increased endogenous BDNF-L mRNA levels. A receptor for BDNF, p75(NTR) , was also suppressed during differentiation and in response to miR-206, but this appeared to not be entirely mediated via a miR-206 target site its 3'UTR. Based on these observations, BDNF represents a novel target through which miR-206 controls the initiation and maintenance of the differentiated state of muscle cells. These results further suggest that miR-206 might play a role in regulating retrograde signaling of BDNF at the neuromuscular junction.