Quantitative adaptation of isoacceptor tRNAs to mRNA codons of alanine, glycine and serine

Genetic Code Expansion of the Silkworm Bombyx mori Using a Pyrrolysyl-tRNA Synthetase/tRNAPyl Pair

The domesticated silkworm Bombyx mori, an essential industrial animal for silk production, has attracted attention as a host for protein production due to its remarkable protein synthesis capability. Here, we applied genetic code expansion (GCE) using a versatile pyrrolysyl-tRNA synthetase (PylRS)/tRNAPyl pair from Methanosarcina mazei to B. mori; GCE enables synthetic amino acid incorporation into proteins to give them non-natural functions. Transgenic B. mori lines expressing M. mazei PylRS and its cognate tRNAPyl were generated and cross-mated to obtain their F1 hybrid. Orally administering a click-compatible synthetic amino acid, trans-cyclooctene-lysine (TCO-Lys), to the F1 hybrid has led to the production of silk fiber incorporated with TCO-Lys. TCO-Lys incorporation in silk fiber was verified by selective labeling of the TCO group by click chemistry. The developed system is available for large-scale protein production with a wide variety of synthetic amino acids.

Target-Cell-Directed Bioengineering Approaches for Gene Therapy of Hemophilia A

Potency is a key optimization parameter for hemophilia A gene therapy product candidates. Optimization strategies include promoter engineering to increase transcription, codon optimization of mRNA to improve translation, and amino-acid substitution to promote secretion. Herein, we describe both rational and empirical design approaches to the development of a minimally sized, highly potent AAV-fVIII vector that incorporates three unique elements: a liver-directed 146-nt transcription regulatory module, a target-cell-specific codon optimization algorithm, and a high-expression bioengineered fVIII variant. The minimal synthetic promoter allows for the smallest AAV-fVIII vector genome known at 4,832 nt, while the tissue-directed codon optimization strategy facilitates increased fVIII transgene product expression in target cell types, e.g., hepatocytes, over traditional genome-level codon optimization strategies. As a tertiary approach, we incorporated ancient and orthologous fVIII sequence elements previously shown to facilitate improved biosynthesis through post-translational mechanisms. Together, these technologies contribute to an AAV-fVIII vector that confers sustained, curative levels of fVIII at a minimal dose in hemophilia A mice. Moreover, the first two technologies should be generalizable to all liver-directed gene therapy vector designs.

Developmental Changes for the Hemolymph Metabolome of Silkworm (Bombyx mori L.)

Silkworm (Bombyx mori) is a lepidopteran-holometabolic model organism. To understand its developmental biochemistry, we characterized the larval hemolymph metabonome from the third instar to prepupa stage using (1)H NMR spectroscopy whilst hemolymph fatty acid composition using GC-FID/MS. We unambiguously assigned more than 60 metabolites, among which tyrosine-o-β-glucuronide, mesaconate, homocarnosine, and picolinate were reported for the first time from the silkworm hemolymph. Phosphorylcholine was the most abundant metabolite in all developmental stages with exception for the periods before the third and fourth molting. We also found obvious developmental dependence for the hemolymph metabonome involving multiple pathways including protein biosyntheses, glycolysis, TCA cycle, the metabolisms of choline amino acids, fatty acids, purines, and pyrimidines. Most hemolymph amino acids had two elevations during the feeding period of the fourth instar and prepupa stage. Trehalose was the major blood sugar before day 8 of the fifth instar, whereas glucose became the major blood sugar after spinning. C16:0, C18:0 and its unsaturated forms were dominant fatty acids in hemolymph. The developmental changes of hemolymph metabonome were associated with dietary nutrient intakes, biosyntheses of cell membrane, pigments, proteins, and energy metabolism. These findings offered essential biochemistry information in terms of the dynamic metabolic changes during silkworm development.

A novel TATA-box-binding factor from the silk glands of the mulberry silkworm, Bombyx mori

The presence of one or more TATATAA motifs in the flanking sequences of individual members of a multi-gene tRNA(Gly)(1) family from the mulberry silkworm, Bombyx mori, negatively modulated the transcription of the gene copies. Characterization of proteins from posterior silk gland nuclear extracts, binding to the TATATAA motif, identified a novel 43 kD protein, designated here as P43 TATA-box-binding factor (TBF). The protein was purified to homogeneity. P43 TBF binding was highly sequence-specific and showed a 100-fold-higher affinity for binding than the TATA-box-binding protein (TBP). The protein also showed binding to the TATAAA sequence of the actin5C promoter. P43 TBF inhibited transcription of all the tRNA genes examined, as well as RNA polymerase II transcription from the actin5C promoter. The amino acid sequence of eleven peptides generated from P43 TBF did not share homology with proteins that bind the TATA box, such as TBP, TRF (TBP-related factor) or TLFs (TBP-like factors) reported from other sources. Inhibition of transcription of tRNA genes by P43 TBF could not be reversed by TBP. The inhibitory effect appeared to be exerted through sequestration of the associated transcription factors.

Characterization of RNA polymerase III transcription factor TFIIIC from the mulberry silkworm, Bombyx mori

Fractionation of nuclear extracts from posterior silk glands of mulberry silkworm Bombyx mori, resolved the transcription factor TFIIIC into two components (designated here as TFIIIC and TFIIIC1) as in HeLa cell nuclear extracts. The reconstituted transcription of tRNA genes required the presence of both components. The affinity purified TFIIIC is a heteromeric complex comprising of five subunits ranging from 44 to 240 kDa. Of these, the 51-kDa subunit could be specifically crosslinked to the B box of tRNA1Gly. Purified swTFIIIC binds to the B box sequences with an affinity in the same range as of yTFIIIC or hTFIIIC2. Although an histone acetyl transferase (HAT) activity was associated with the TFIIIC fractions during the initial stages of purification, the HAT activity, unlike the human TFIIIC preparations, was separated at the final DNA affinity step. The tRNA transcription from DNA template was independent of HAT activity but the repressed transcription from chromatin template could be partially restored by external supplementation of the dissociated HAT activity. This is the first report on the purification and characterization of TFIIIC from insect systems.

Differential expression of individual gene copies from within a tRNA multigene family in the mulberry silkworm Bombyx mori

In mulberry silkworm Bombyx mori, tRNA1(Gly) constitutes a multigene family from which the individual members are transcribed at different levels in vitro in homologous nuclear extracts. We report here the quantification of functional transcripts of these gene copies in vivo in B. mori-derived BmN cells based on a suppression assay. The gene copies were converted to encode suppressor tRNAs and co-transfected into cell lines with reporter gene(s) harbouring one or more nonsense mutations and the reporter gene activity was quantified. Individual members of the gene family were transcribed to very high-, medium- and very low-levels, following the same pattern as in vitro. All these gene copies were maximally expressed in Bm cells as compared to other insect cell lines.

Transcriptional silencing of a tRNA1Gly copy from within a multigene family is modulated by distal cis elements

Individual copies of tRNA1Gly from within the multigene family in Bombyx mori could be classified based on in vitro transcription in homologous nuclear extracts into three categories of highly, moderately, or weakly transcribed genes. Segregation of the poorly transcribed gene copies 6 and 7, which are clustered in tandem within 425 base pairs, resulted in enhancement of their individual transcription levels, but the linkage itself had little influence on the transcriptional status. For these gene copies, when fused together generating a single coding region, transcription was barely detectable, which suggested the presence of negatively regulating elements located in the far flanking sequences. They exerted the silencing effect on transcription overriding the activity of positive regulatory elements. Systematic analysis of deletion, chimeric, and mutant constructs revealed the presence of a sequence element TATATAA located beyond 800 nucleotides upstream to the coding region acting as negative modulator, which when mutated resulted in high level transcription. Conversely, a TATATAA motif reintroduced at either far upstream or far downstream flanking regions exerted a negative effect on transcription. The location of cis-regulatory sequences at such farther distances from the coding region and the behavior of TATATAA element as negative regulator reported here are novel. These element(s) could play significant roles in activation or silencing of genes from within a multigene family, by recruitment or sequestration of transcription factors.

Differential transcription of multiple copies of a silk worm gene encoding tRNA(Gly1)

Ten different tRNA(Gly1) genes from the silk worm, Bombyx mori, have been cloned and characterized. These genes were transcribed in vitro in homologous nuclear extracts from the posterior silk gland (PSG) or nuclear extracts derived from the middle silk gland or ovarian tissues. Although the transcription levels were much higher in the PSG nuclear extracts, the transcriptional efficiency of the individual genes followed a similar pattern in all the extracts. Based on the levels of in vitro transcription, the ten tRNA(Gly1) genes could be divided into three groups, viz., those which were transcribed at very high levels (e.g., clone pR8), high to medium levels (e.g., pBmi1, pBmp1, pBmh1, pBmt1) and low to barely detectable levels (e.g., pBms1, pBmj1 and pBmk1). The coding sequences of all these tRNA genes being identical, the differential transcription suggested that the flanking sequences modulate their transcriptional efficiency. The presence of positive and negative regulatory elements in the 5' flanking regions of these genes was confirmed by transcription competition experiments. A positive element was present in the immediate upstream A+T-rich sequences in all the genes, but no consensus sequences correlating to the transcriptional status could be generated. The presence of negative elements on the other hand was indicated only in some of the genes and therefore may have a role in the differential transcription of these tRNA(Gly1) genes in vivo.

Expression of the Synechocystis sp. strain PCC 6803 tRNA(Glu) gene provides tRNA for protein and chlorophyll biosynthesis

In the cyanobacterium Synechocystis sp. strain PCC 6803 (Synechocystis 6803) delta-aminolevulinic acid (ALA), the sole precursor for the synthesis of the porphyrin rings of heme and chlorophyll, is formed from glutamate activated by acylation to tRNA(Glu) (G. P. O'Neill, D. M. Peterson, A. Schön, M. W. Chen, and D. Söll, J. Bacteriol. 170:3810-3816, 1988; S. Rieble and S. I. Beale, J. Biol. Chem. 263:8864-8871, 1988). We report here that Synechocystis 6803 possesses a single tRNA(Glu) gene which was transcribed as monomeric precursor tRNA and matured into the two tRNA(Glu) species. They differed in the extent of modification of the first anticodon base, 5-methylaminomethyl-2-thiouridine (O'Neill et al., 1988). The two tRNA species had equivalent capacities to stimulate the tRNA-dependent formation of ALA in Synechocystis 6803 and to provide glutamate for protein biosynthesis in an Escherichia coli-derived translation system. These results are in support of a dual role of tRNA(Glu). The levels of tRNA(Glu) were examined by Northern (RNA) blot analysis of cellular RNA and by aminoacylation assays in cultures of Synechocystis 6803 in which the amount of chlorophyll synthesized was modulated over a 10-fold range by various illumination regimens or by the addition of inhibitors of chlorophyll and ALA biosynthesis. In these cultures, the level of tRNA(Glu) was always a constant fraction of the total tRNA population, suggesting that tRNA(Glu) and chlorophyll levels are regulated independently. In addition, the tRNA(Glu) was always fully aminoacylated in vivo.

Two cyclic AMP-regulated genes from Dictyostelium discoideum encode homologous proteins

Expression of the 7E and 2C genes late in Dictyostelium development ceases upon cell disaggregation but, in contrast to many other genes we have studied, expression is fully restored by exogenous cAMP (A. J. Richards et al., submitted). The 7E and 2C genes encode polypeptides of similar size (9220 and 10573 Daltons, respectively), each of which contains an unusually high proportion of serine plus glycine residues (41% and 59%, respectively). Each protein possesses a relatively serine-rich N-terminus and glycine-rich C-terminus and contains the conserved sequence S(X)SSS(X2)SS(X)SS(X2)SFGS. These data suggest that genes 7E and 2C may have arisen by duplication of a common ancestor. Computer analysis indicates that both gene products are probably intracellular structural proteins that form extended coil structures.

The transcriptional efficiency of clustered tRNA genes is affected by their position within the cluster

The transcription of a mouse genomic segment containing four tRNA genes, coding for a tRNA(Ala), a tRNA(Ile), a tRNA(Pro) and a tRNA(Lys), has been studied in a HeLa cell extract, demonstrating that differences among their transcriptional efficiencies are evident using as templates either the natural cluster or an equimolecular mixture of the four isolated genes. Nevertheless, the structure of the cluster influences the transcriptional efficiency of the clustered genes. In fact, a cis-acting inhibitory sequence has been located at about 400 bp downstream of the tRNA(Pro) coding sequence. Moreover rearrangements of the reciprocal position of the various tRNA genes within the cluster results in significant changes in the transcriptional rates of the individual transcriptional units.

Structure and in vitro transcription of tRNA gene clusters containing the primers of MuLV reverse transcriptase

Three genes coding for mouse tRNAPro have been isolated from a genomic library and characterized both structurally and functionally. Two of these (tPro52 and tPro53) code for the tRNA primer of reverse transcriptase of MuLV. The third one (tPro51) shows several differences (mutations and deletions) that probably prevent the folding of the matured transcript into the cloverleaf structure, and is therefore a pseudogene. This pseudogene gives rise to a RNA transcription product in vitro. tPro52 is clustered with a tRNALys gene and with a tRNAAla gene, which is strongly homologous to the rat identifier repeated sequence. tPro53 is clustered with a tRNAAsp and a tRNAGly gene. Other tRNA-hybridizing sequences are present in the lambda clones that contain tPro51 and tPro53.

Control of RNA and protein synthesis by the concentration of Trp-tRNATrp in Escherichia coli infected with bacteriophage MS2

The effect of varying the concentration of Trp-tRNATrp in Escherichia coli infected with bacteriophage MS2 has been studied by varying the amount of exogenously added tryptophan (Trp) to cells bearing a mutation which results in a tryptophanyl-tRNA synthetase with a higher Km value for Trp. The phenotype of the mutant has been confirmed by measuring the level of tRNATrp which can be aminoacylated in vivo, and the mutant has also been shown to have elevated tRNATrp levels compared to wild-type. The growth of MS2 decreases continuously with decreasing Trp concentration (and hence, decreasing Trp-tRNATrp concentration). This appears to be due to reduced gene expression, since at later times in infection the amount of MS2 coat protein synthesized likewise decreases continuously with decreasing Trp concentration. However, there is little decrease in the amount of coat protein or replicase synthesized during the first few minutes after the Trp concentration shift. A continuous increase in the average polysome size distribution is seen as the Trp concentration is decreased. MS2 RNA synthesis also decreases continuously with decreasing Trp concentration, and is shut off in the absence of Trp. This does not seem to be due to ppGpp as these cells are functionally relaxed under these conditions, nor does it seem to be due to degradation of pre-existing template. Addition of chloramphenicol abolishes the effect of Trp concentration on RNA synthesis. The data are consistent with a model in which ribosomes pause at Trp codons in the absence of Trp-tRNATrp, while other ribosomes queue behind and continue to load onto the message. The reduction of RNA synthesis would then be a consequence of coupling to translation.

Differential synthesis rates of tRNA species in the silk gland of Bombyx mori are required to promote tRNA adaptation to silk messages

In studying the mechanism of tRNA adaptation to silk fibroin and sericin mRNA translation, we investigated the accumulation rates of tRNA species rapidly labeled in vivo in the posterior and middle silk glands of the silkworm Bombyx mori during the last larval instar. We found that the rates of synthesis of total and individual tRNA species labeled with [3H]uridine during the growth and the secretion phases and separated by electrophoresis on polyacrylamide gels, are specific for each tRNA species and each tissue. We noted continuous variations of the tRNA levels designed to reflect changes in the population of mRNAs. The tRNA adaptation to silk mRNAs is completed roughly at the end of the growth phase and at the beginning of the secretion phase (day four of the Vth instar). Its stabilization during the secretion phase occurs by a reversal of the relative rates of predominant tRNA species, mainly tRNAGly. The sum total of the synthetic rates for each tRNA species corroborates their known adaptive distribution during the secretion phase of silk proteins. In addition, when coupled to the similarity of their turnover rates, observed previously, the data support a transcriptional control of tRNA genes.

Differential usage of iso-accepting tRNASer species in silk glands of Bombyx mori

The rapid development of the silk glands of Bombyx mori during the last larval instar shows two phases. During the first 4 days, in both the middle and posterior parts of the silk glands, the ribosomal machinery is assembled and the synthesis of housekeeping proteins starts. During the second phase (the last 4 days), the middle part of the gland synthesis approximately 45 mg of the silk protein sericin (31% serine) and the posterior part of the gland synthesizes approximately 130 mg of the silk protein fibroin (46% glycine, 29% alanine and 12% serine). Silk fibroin and sericin are detectable by the second day and represent 80 and 50% respectively of the total proteins produced at day 8 (refs 1--4). It is known that the tRNA population of the posterior part of the gland is quantitatively adapted to fibroin codon frequency during this period but little is known about the situation in the middle part except for the observation that it contains more tRNASer than does the posterior part. We show here that the two parts contain, and presumably use, different iso-accepting species of tRNASer, the middle part using tRNASer1, which recognizes AGU and AGC codons, and the posterior part using tRNASer2 which recognizes UCA. We also suggest that this differential adaptation of the tRNASer species is under transcriptional control as the two species are accumulated at different rates, but degraded at the same rate.

Does quantitative tRNA adaptation to codon content in mRNA optimize the ribosomal translation efficiency? Proposal for a translation system model

Neither a dynamic nor an energetic approach of the translation process has taken into account that intracellular levels of iso-tRNA species are adapted or adjusted to the codon frequency of mRNA being decoded (Bombyx mori silk gland, rabbit reticulocyte). A critical study of available experimental data suggests that the average elongation rate of a protein is maximized in the presence of an adapted tRNA population, usually an homologous tRNA. In addition, the amount of synthesized protein parallels that of corresponding mRNA. Other evidences--including in vitro and in vivo elongation assays with fibroin mRNA--show that individual elongation rates are not uniform. Pauses occur at certain sites of the mRNA chain. The relative lifetime of these pauses depends on the tRNA pool used. Finally, it appears that translation accuracy also depends on the balanced tRNA population. We propose to explain these different effects by using a codon-anticodon recognition model, called "trial and error system" based on a stochastic processing of the ribosome. Accordingly, various acylated tRNA species which surround a ribosome randomly encounter the receptor A site. Every trapped tRNA species is tested for a proper pairing with the codon to be recognized at the level of a comparator or discriminator function. If the pairing is correct, transpeptidation becomes irreversible. If not, the aminoacyl-tRNA is rejected and another randomly trapped tRNA is processed in turn. Mathematical analysis of this model shows that the mean number of trials used for translating the whole sequence of a mRNA is minimized when the proportion of different iso-tRNA species is correlated with the square root of codon frequency. Quantitations of reticulocyte tRNA support such a parabolic relation. Our translation system model brings some light into the role of tRNA adaptation for optimizing translation efficiency, i.e. maximizing both speed and accuracy. Some consequences of the model are discussed.

The evolving tRNA molecule

The study of tRNA molecular evolution is crucial to understanding the origin and establishment of the genetic code as well as the differentiation and refinement of the machinery of protein synthesis in prokaryotes, eukaryotes, organelles, and phage systems. The small size of the molecule and its critical involvement in a multiplicity of roles distinguish its study from classical protein molecular evolution with respect to goals and methods. Here, the authors assess available and missing data, existing and needed methodology, and the impact of tRNA studies on current theories both of genetic code evolution and of the evolution of species. They analyze mutational "hot spots", the role of base modification, synthetase recognition, codon-anticodon interactions and the status of organelle tRNA.

Changes in the serine-specific transfer ribonucleic acid pattern of guinea pig epidermis after corticosteroid treatment

The pattern of serine-specific tRNAs from guinea pig epidermis was determined and compared to that from liver by employing reversed phase chromatography on total tRNA preparations aminoacylated with 3H- or 14C-serine. Five tRNAserS (I-V) were found, two of which, tRNAserI and tRNAserV, appear to be "typical" for epidermis and in so far probably reflect in some way metabolic peculiarities of epidermal cell differentiation. This hypothesis was further corroborated by showing that the locally applied corticosteroid triamcinolon selectively increases tRNAserI and tRNAserV 2-3-fold. The implications of these findings were discussed in detail.

Preferential binding of isoaccepting species of tRNALys and tRNAIle from lupin cotyledons to polyribosomes

Polyribosome-bound and -unbound isoaccepting species of tRNALys and tRNAIle, isolated from lupin cotyledons, were compared by RPC-5 chromatography and it was found that polyribosomes preferentially bind some of the isoaccepting species. The preference in binding of given isoacceptors changes with the age of lupin seedling. The results suggest that the tRNALys species recognising the same codons can affect the rate of translation in lupin cotyledons.

Nucleotide sequence of three isoaccepting lysine tRNAs from rabbit liver and SV40-transformed mouse fibroblasts

The lysine isoacceptor tRNAs differ in two aspects from the majority of the other mammalian tRNA species: they do not contain ribosylthymine (T) in loop IV, and a 'new' lysine tRNA, which is practically absent in non-dividing tissue, appears at elevated levels in proliferating cells. We have therefore purified the three major isoaccepting lysine tRNAs from rabbit liver and the 'new' lysine tRNA isolated from SV40-transformed mouse fibroblasts, and determined their nucleotide sequences. Our basic findings are as follows. a) The three major lysine tRNAs (species 1, 2 and 3) from rabbit liver contain 2'-O-methylribosylthymine (Tm) in place of T. tRNA1Lys and tRNA2Lys differ only by a single base pair in the middle of the anticodon stem; the anticodon sequence C-U-U is followed by N-threonyl-adenosine (t6A). TRNA3Lys has the anticodon S-U-U and contains two highly modified thionucleosides, S (shown to be 2-thio-5-carboxymethyl-uridine methyl ester) and a further modified derivative of t6 A (2-methyl-thio-N6-threonyl-adenosine) on the 3' side of the anticodon. tRNA3Lys differs in 14 and 16 positions, respectively, from the other two isoacceptors. b) Protein synthesis in vitro, using synthetic polynucleotides of defined sequence, showed that tRNA2Lys with anticodon C-U-U recognized A-A-G only, whereas tRNA3Lys, which contains thio-nucleotides in and next to the anticodon, decodes both lysine codons A-A-G and A-A-A, but with a preference for A-A-A. In a globin-mRNA-translating cell-free system from ascites cells, both lysine tRNAs donated lysine into globin. The rate and extent of lysine incorporation, however, was higher with tRNA2Lys than with tRNA3Lys, in agreement with the fact that alpha-globin and beta-globin mRNAs contain more A-A-G than A-A-A- codons for lysine. c) A comparison of the nucleotide sequences of lysine tRNA species 1, 2 and 3 from rabbit liver, with that of the 'new' tRNA4Lys from transformed and rapidly dividing cells showed that this tRNA is not the product of a new gene or group of genes, but is an undermodified tRNA derived exclusively from tRNA2Lys. Of the two dihydrouridines present in tRNA2Lys, one is found as U in tRNA4Lys; the purine next to the anticodon is as yet unidentified but is known not be t6 A. In addition we have found U, T and psi besides Tm as the first nucleoside in loop IV.

Transfer ribonucleic acids from eleven immunoglobulin-secreting mouse plasmacytomas. Constant and variable chromatographic profiles compared with the myeloma protein sequences

In order to test the concepts that aminoacyl-tRNAs in plasmacytomas may on the one hand modulate the protein synthesized or on the other hand reflect the structure of the synthesized protein, the RPC-5 chromatographic profiles of aminoacyl-tRNAs for all 20 amino acids were studied in tRNA prepared from normal mouse liver and 11 plasmacytomas. The patterns of isoaccepting tRNA were compared with the structure of the myeloma protein being synthesized. The elution profiles of aminoacyl-tRNAs for nine of the amino acids were constant, i.e. they were the same for liver and all plasmacytomas. Significant variability was observed in the profiles of the other 11 families of aminoacyl-tRNAs: asparagine, serine and tryptophan, had peaks of isoaccepting tRNAs found in tumors and not in liver; glutamic acid, histidine and lysine, had different patterns of aminoacyl-tRNAs in plasmacytomas which could be distinguished from the elution profile of liver; and isoleucine, proline, threonine and tyrosine, showed pattern variability in only a few of the tumors. Valyl-tRNA uniquely had one isoacceptor present in liver but absent in the tumors. This variability is thought to be associated with different posttranscriptional modification of the tRNAs rather than regulation of individual tRNA genes in response to particular amino acid sequences in secreted myeloma proteins. Similarily, the lack of correlation of isoacceptors with sequence differences makes the modulation of protein fine structure by tRNA availability unlikely.

Effect of starvation on tRNA synthesis, amino acid pool, tRNA charging levels and aminoacyl-tRNA synthetase activities in the posterior silk gland of Bombyx mori L

Changes in the translational machinery components of the Bombyx mori posterior silk gland were analysed during starvation and refeeding and compared to the regularly fed larvae. During starvation, tRNA and ribosomal RNA synthesis are stopped. The amounts of different RNA classes and of the different tRNA species slow down at the same rate. Thus various tRNA show similar half-lifes and the preexisting tRNA adaptation to fibroin mRNA translation persists during starvation. Similarly, the tRNA/rRNA ratio is constant during starvation and refeeding (12 tRNA molecules for one ribosome) as in silk glands of control animals. Aminoacyl-tRNA synthetases and tRNA charging levels are decreased during starvation. The maximal tRNA charging level obtained during maximal protein synthesis in control animals is regained after 24 h refeeding of starved larvae. Changes observed in the free amino acid pool are not similar from one amino acid to another and levels reached after starvation do not differ strongly from the controls. Our results suggest that the production of translation apparatus components is coordinated and adjusted to the protein synthesis activity. Whether this coordination occurs in the silk gland is discussed on the basis of the "metabolic regulation", primarily described in prokaryotes and Yeast. Transfer RNA charging levels seem to play a key role in the process of regulation and could be implicated in the mechanism of tRNA adaptation if this phenomenon results as expected from a transcriptional control.

Studies on tRNA adaptation, tRNA turnover, precursor tRNA and tRNA gene distribution in Bombyx mori by using two-dimensional polyacrylamide gel electrophoresis

Eighteen out of twenty amino acids have been used for identifying tRNAs from the silkworm Bombyx mori L. fractionated on two-dimensional polyacrylamide gel electrophoresis. 43 spots out of 53 have been identified. This mapping confirms previous results and brings new answers to some questions on the regulation of tRNA biosynthesis. 1. In addition to quantitative adaptation of tRNAs to the composition of silk proteins (fibroin from the posterior silk gland, sericin from the middle part) and of iso-tRNAs from posterior silk gland to the major codons of fibroin mRNA, we also observe adaptation of tRNA from various tissues to the average amino acid content of proteins from fat body, gut, gonads and carcass of the silkworm. 2. In the silk gland, turnover rates of several tRNA species are similar. The selective accumulation of tRNAs needed for decoding fibroin and sericin mRNAs which takes place during the Vth larval instar, cannot be explained by the occurrence of a preferential degradation of some tRNA species. 3. Under given conditions for incubating silk glands, it is possible to obtain an accumulation of precursor tRNA species, which are enriched in pre-tRNAAla and pre-tRNAGly in the posterior silk gland and pre-tRNASer in the middle part. 4. The distribution of tRNA genes is not random. tRNA genes for glycine, alanine and serine are prominent. Selective transcription of batteries of iso-tRNA genes could explain our data.

Quantitative data on the Bombyx mori L. silkworm: a review

This paper summarizes a variety of quantitative data on the silkworm Bombyx mori, collected in the literature, to help building models on silk gland differentiation. The properites of the silk gland and their changes especially during the last larval instar have been reviewed (size, DNA, RNA amino acids, enzymes). The components of the silk (fibroin and sericin) are also studied (molecular weight, composition). Thus translation and transcription rates have been estimated. The relevant data on the fat body and the haemolymph are also given, as well as some characteristics of the oocyte/egg system.

The adaptation of the silkgland cell to the production of fibroin in Bombyx mori L

At the end of the larval life, the posterior silk gland of Bombyx mori is highly specialized in the biosynthesis of a specific protein : silk fibroin. The successive steps of fibroin production : amino supply, synthesis and secretion are described. Their analysis shows that fibroin synthesis is important enough to orient the overall cellular activities. Thus, the terminal differentiation of the posterior silk gland cell corresponds to the cells adaptation to the production of fibroin. Cytological and biochemical studies of the silk gland development show that specialization occurs discontinuously; the fourth molt, when fibroin is no more produced, is a phase of regression of the cellular adaptation whereas cell differentiation proceeds during the growth phase of the following fifth intermolt. After the spinning of the cocoon, the cells are lysed and disappear entirely at the nymphal stage. Biometrical analysis of silk production of different Bombyx strains in relation with the development of the proteosynthesis apparatus leads to the conclusion that the specific messenger RNA content determines the amount of synthetized fibroin. At maximum secretion, the mRNAF recruits almost all the cell ribosomes. The variations of the size of the proteosynthesis machinery are sufficient to explain the differences of productivity of the various silkworm strains. Different experimental factors affect silk production. Topical applications of juvenile hormone induce an increase of the RNA content and a consequent rise of the amount of secreted protein. In contrast, starvation reduces the silk production by acting at both transcriptonal and translational levels. Current researches on this system are devoted to the study of the differential gene expression, with particular interest to the regulation of the transcription of the specific fibroin messenger RNA.

Nucleotide sequence of the simian virus 40 Hind II + III restriction fragment J and the total amino acid sequence of the major structural protein VP1

The HindII + III restriction fragment J (Hind-J) represents 4.58% of the simian virus 40 genome. The information present in Hind-J is expressed as part of the major, late 16-S messenger RNA, which codes for the structural protein VP1. The nucleotide sequence of the 240-base-pairs-long Hind fragment J has been determined by analysis of each oligonucleotide from both strands resulting from T1 or pancreatic RNase digestion of RNA transcribed from the DNA and from RNase digestion of ribo-substituted DNA. Large oligonucleotide blocks which could be constructed mainly on the basis of complementarity were subsequently ordered by partial chemical degradation of terminally labeled DNA. This direct DNA sequencing approach also completely confirmed the results obtained by both aforementioned RNase degradation methods. In the strand with the same polarity as the late mRNA, triplets corresponding to termination codons are present in two of the three reading frames. The one open reading frame connects in phase with the open reading frame of the neighboring HindII/ III fragments K, F and G, which have been published previously and which together with Hind-J span the total VP1 gene. Some features of the primary nucleotide sequence of this VP1 gene and the derived VP1 amino acid sequence are discussed.

Structural studies on RNA from Bombyx mori L. I. Nucleoside composition of enriched tRNA species from the posterior silkgland purified by coutercurrent distribution

A large scale fractionation of tRNA from the posterior silkgland of the silkworm Bombyx mori L. by countercurrent distribution is described. One single 1,500 transfer distribution carried out with Phosphate buffer-Fromamide-Isopropanol (PFI) solvent system yields highly enriched isoaccepting species with increasing mobility order: tRNA1Gly, tRNA1-2Ala, tRNATyr, tRNA2Gly, tRNA1Ser and tRNA2Ser with 75%, 70%, 90%, 60%, 60%, and 90% purities respectively. Nucleosides fingerprint analysis of each iso-tRNA species confirms the anticodon structures previously suggested for tRNA2Ala (IGC), tRNA2bGly (U-CC) (U-CC) and tRNA2bSer (IGA). Twenty two minor nucleosides, three of them with unknown structure, have been detected. They are: m5C in tRNA1Gly, m1I in all tRNAAla species, polar A and U called X in tRNATyr, polar U derivative in tRNAGly2, mt6A in tRNASer1 and i6A tRNA2Ser. Both tRNASer species have m3C and ac7C. We do not detect Q, Y and thiol derivatives. The elution characteristics of silkgland tRNA species may be expressed in a semilogarithmic diagram where log K (K is the partition coefficient) is related to the base ratio A/Y) and the coding properties. The distribution pattern of silkgland tRNAs has been compared with that of Yeast and Rat liver tRNAs fractionated by countercurrent distribution with the PFI and PMB (Potassium phosphate buffer, 2-methoxy ethanol, 2-butoxy ethanol) solvent systems.