Characterization of Streptomyces MITKK-103, a newly isolated actinomycin X2-producer.

A new actinomycete strain designated MITKK-103 was isolated from the soil of a flowerpot using a humic acid agar medium. The newly isolated strain was able to produce a large amount of actinomycin X2 even under nonoptimized growing conditions and serves as a promising source of this antibiotic. Actinomycin X2 has higher cytotoxicity toward cultured human leukemia (HL-60) cells than does actinomycin D, and it induces cell death via apoptosis. A nearly complete 16S ribosomal DNA (rDNA) sequence from the isolate was determined and found to have high identity (98.5-100%) with Streptomyces galbus, Streptomyces griseofuscus, and Streptomyces padanus, indicating that MITKK-103 belongs to the genus Streptomyces. The isolate clustered with species belonging to the S. padanus clade in a 16S-rDNA-based phylogenetic tree and showed 75% overall homology to S. padanus ATCC 25646 in DNA-DNA relatedness analysis. Although the growth of the isolate was somewhat different from the three species mentioned, the strain MITKK-103 most closely resembles S. padanus on the basis of the morphological and phenotypic characteristics, phylogenetic analysis, and genotypic data. As such, this is the first report of a strain of S. padanus capable of producing actinomycins.

Disparity between changes in mRNA abundance and enzyme activity in Corynebacterium glutamicum: implications for DNA microarray analysis.

The relationship between changes in mRNA abundance and enzyme activity was determined for three genes over a span of nearly 3 h during amino acid production in Corynebacterium glutamicum. Gene expression changes during C. glutamicum fermentations were examined by complementary DNA (cDNA) microarrays and by a second method for quantitating RNA levels, competitive reverse transcriptase-PCR (RT-PCR). The results obtained independently by both methods were compared and found to be in agreement, thus validating the quantitative potential of DNA microarrays for gene expression profiling. Evidence of a disparity between mRNA abundance and enzyme activity is presented and supports our belief that it is difficult to generally predict protein activity from quantitative transcriptome data. Homoserine dehydrogenase, threonine dehydratase, and homoserine kinase are enzymes involved in the biosynthesis of l-isoleucine and other aspartate-derived amino acids in C. glutamicum. Our data suggest that different underlying regulatory mechanisms may be connected with the expression of the genes encoding each of these three enzymes. Indeed, whereas in one case the increases in enzyme activity exceeded those in the corresponding mRNA abundance, in another case large increases in the levels of gene expression were not congruent with changes in enzyme activity.

Engineering an indene bioconversion process for the production of cis-aminoindanol: a model system for the production of chiral synthons.

Cis-aminoindanol, a key chiral precursor to the HIV protease inhibitor CRIXIVAN, can be derived from indene oxidation products of (2R) stereochemistry. A number of different microorganisms, notably strains of the genera Pseudomonas and Rhodococcus, have been isolated that catalyze the oxygenation of indene to indandiol with greater stereospecificity than is achievable through traditional chemical synthesis. The yield and ultimate optical purity of indandiol produced in such biocatalytic processes is influenced by the intrinsic stereospecificity of the oxygenase(s), enantioselective dehydrogenation, and the loss of substrate to alternate, undesirable metabolites. Metabolic engineering of any indene bioconversion system for the commercial-scale production of cis-aminoindanol must account for these influences, as well as pathway fluxes and enzyme regulation, to optimize the formation of oxygenated precursors with useful stereochemistry. As such, the process by which bacterial systems carry out the bioconversion of indene to indandiol serves as a model for biological production of industrially relevant chiral synthons.

Development and validation of corynebacterium DNA microarrays.

We have developed DNA microarray techniques for studying Corynebacterium glutamicum. A set of 52 C. glutamicum genes encoding enzymes from primary metabolism was amplified by PCR and printed in triplicate onto glass slides. Total RNA was extracted from cells harvested during the exponential-growth and lysine production phases of a C. glutamicum fermentation. Fluorescently labeled cDNAs were prepared by reverse transcription using random hexamer primers and hybridized to the microarrays. To establish a set of benchmark metrics for this technique, we compared the variability between replicate spots on the same slide, between slides hybridized with cDNAs from the same labeling reaction, and between slides hybridized with cDNAs prepared in separate labeling reactions. We found that the results were both robust and statistically reproducible. Spot-to-spot variability was 3.8% between replicate spots on a given slide, 5.0% between spots on separate slides (though hybridized with identical, labeled cDNA), and 8.1% between spots from separate slides hybridized with samples from separate reverse transcription reactions yielding an average spot to spot variability of 7.1% across all conditions. Furthermore, when we examined the changes in gene expression that occurred between the two phases of the fermentation, we found that results for the majority of the genes agreed with observations made using other methods. These procedures will be a valuable addition to the metabolic engineering toolbox for the improvement of C. glutamicum amino acid-producing strains.

Metabolic redirection of carbon flow toward isoleucine by expressing a catabolic threonine dehydratase in a threonine-overproducing Corynebacterium glutamicum.

Carbon destined for lysine synthesis in Corynebacterium glutamicum ATCC 21799 can be diverted toward threonine by overexpression of genes encoding a feedback-insensitive homoserine dehydrogenase (hom(dr)) and homoserine kinase (thrB). We studied the effects of introducing two different threonine dehydratase genes into this threonine-producing system to gauge their effects on isoleucine production. Co-expression of hom(dr), thrB, and ilvA, which encodes a native threonine dehydratase, caused isoleucine to accumulate to a final concentration of 2.2+/-0.2 g l(-1), five-fold more than accumulates in the wild-type strain, and approximately twice as much as accumulates in the strain expressing only hom(dr) and thrB. Comparing these data with previous results, we found that overexpression of the three genes, hom(dr), thrB, and ilvA, in C. glutamicum ATCC 21799 is no better in terms of isoleucine production than the expression of a single gene, tdcB, encoding a catabolic threonine dehydratase from Escherichia coli. Co-expression of hom(dr), thrB, and tdcB, however, caused the concentration of isoleucine to increase 20-fold compared to the wild-type strain, about four times more than the corresponding ilvA-expressing strain. In this system, the apparent yield of isoleucine production was multiplied by a factor of two [2.1 mmol (g dry cell weight)(-1)]. While the balance of excreted metabolites showed that the carbon flow in this strain was completely redirected from the lysine pathway into the isoleucine pathway, it also showed that more pyruvate was diverted into amino acid synthesis.

Expression of the Escherichia coli catabolic threonine dehydratase in Corynebacterium glutamicum and its effect on isoleucine production.

The catabolic or biodegradative threonine dehydratase (E.C. 4.2.1. 16) of Escherichia coli is an isoleucine feedback-resistant enzyme that catalyzes the degradation of threonine to alpha-ketobutyrate, the first reaction of the isoleucine pathway. We cloned and expressed this enzyme in Corynebacterium glutamicum. We found that while the native threonine dehydratase of C. glutamicum was totally inhibited by 15 mM isoleucine, the heterologous catabolic threonine dehydratase expressed in the same strain was much less sensitive to isoleucine; i.e., it retained 60% of its original activity even in the presence of 200 mM isoleucine. To determine whether expressing the catabolic threonine dehydratase (encoded by the tdcB gene) provided any benefit for isoleucine production compared to the native enzyme (encoded by the ilvA gene), fermentations were performed with the wild-type strain, an ilvA-overexpressing strain, and a tdcB-expressing strain. By expressing the heterologous catabolic threonine dehydratase in C. glutamicum, we were able to increase the production of isoleucine 50-fold, whereas overexpression of the native threonine dehydratase resulted in only a fourfold increase in isoleucine production. Carbon balance data showed that when just one enzyme, the catabolic threonine dehydratase, was overexpressed, 70% of the carbon available for the lysine pathway was redirected into the isoleucine pathway.

Isolation and characterization of indene bioconversion genes from Rhodococcus strain I24.

Rhodococcus strain 124 is able to convert indene into indandiol via the actions of at least two dioxygenase systems and a putative monooxygenase system. We have identified a cosmid clone from 124 genomic DNA that is able to confer the ability to convert indene to indandiol upon Rhodococcus erythropolis SQ1, a strain that normally can not convert or metabolize indene. HPLC analysis reveals that the transformed SQ1 strain produces cis-(1R,2S)-indandiol, suggesting that the cosmid clone encodes a naphthalenetype dioxygenase. DNA sequence analysis of a portion of this clone confirmed the presence of genes for the dioxygenase as well as genes encoding a dehydrogenase and putative aldolase. These genes will be useful for manipulating indene bioconversion in Rhodococcus strain 124.

Characterization of IS1676 from Rhodococcus erythropolis SQ1.

To develop a transposable element-based system for mutagenesis in Rhodococcus, we used the sacB gene from Bacillus subtilis to isolate a novel transposable element, IS1676, from R. erythropolis SQ1. This 1693 bp insertion sequence is bounded by imperfect (10 out of 13 bp) inverted repeats and it creates 4 bp direct repeats upon insertion. Comparison of multiple insertion sites reveals a preference for the sequence 5'-(C/T)TA(A/G)-3' in the target site. IS1676 contains a single, large (1446 bp) open reading frame with coding potential for a protein of 482 amino acids. IS1676 may be similar to an ancestral transposable element that gave rise to repetitive sequences identified in clinical isolates of Mycobacterium kansasii. Derivatives of IS1676 should be useful for analysis of Rhodococcus strains, for which few other genetic tools are currently available.

Upstream regulatory sequences from two beta-conglycinin genes.

Genes encoding the beta-conglycinin seed storage proteins of soybean are expressed only in seeds during specific stages of development. The different subunits of beta-conglycinin, alpha', alpha and beta, are encoded by distinct members of a gene family. Yet there are marked differences in the regulation of the genes encoding the alpha'/alpha and beta subunits. Previous work (Chen et al., EMBO J 7: 297-302, 1988) identified a seed specific transcriptional enhancer upstream of a gene encoding the alpha' subunit. Mutations were made within this region to discern its functional components. Among those identified is a 62 bp region (between -77 and -140) that contains a vicilin box consensus sequence as well as a sequence that binds the soybean nuclear factor SEF4 in vitro. A second region, which contains a sequence homologous to the core of the legumin box consensus (i.e., CATGCAT-like or RY repeat element) at -246, was also shown to affect the activity of this enhancer in transgenic plants. A series of 5' terminal deletions were used to identify regulatory elements upstream of the beta subunit gene. Two regions were identified (from -553 to -442 and from -308 to -72) that, when deleted, led to a marked reduction in gene expression. Both of these elements contain sequences that bind SEF4 in vitro. The distal element also contains an AT-rich segment that recognizes a second nuclear factor, SEF1, in vitro. Neither of these elements contains any homology to the vicilin box consensus.

Inactivation of the nopaline synthase gene by double transformation: reactivation by segregation of the induced DNA.

Tobacco plants were transformed with derivatives of a binary vector pMON505 and two kanamycin resistant lines that were nopaline positive were selected for second transformation. The plasmids used for the second transformation were derivatives of pMON850 which carries the nopaline synthase gene in addition to a gene for gentamicin resistance. Insertion of each transgene was confirmed by Southern hybridization. Surprisingly, we found that more than 50% of the doubly transformed tobacco plants were nopaline negative. Tobacco plants that were transformed only by the second vector exhibited nopaline accumulation. DNA methylation patterns at the HpaII site in the promoter region of the nopaline synthase gene did not correlate with the nopaline phenotype. In some plant lines, seedlings of the R1 generation which segregated out the second T-DNA insertion recovered the nop(+) phenotype. These results indicate that nopaline accumulation was inhibited by the presence of the second T-DNA.

Seed-specific repression of GUS activity in tobacco plants by antisense RNA.

beta-Conglycinin, the 7S storage protein of soybean, is expressed only in seeds and is regulated predominantly by gene transcription [5]. We applied an antisense strategy to modify expression of a beta-glucuronidase (uidA or gusA) gene in seeds using a promoter from a beta-conglycinin gene. Transgenic tobacco plants harboring the gusA gene under the control of the CaMV 35S promoter were retransformed with a gene construct comprising the beta-conglycinin promoter fused to the gusA gene in the antisense orientation. Double transformants were regenerated and transformation was confirmed by Southern blot hybridization. Seed-specific repression of GUS activity was observed in lines containing high copy numbers of the antisense gusA transgene. Suppression of GUS activity was correlated with the amounts of (-) sense gusA transcript detected and concomitantly with a decrease in gusA transcript levels. Furthermore, the amount of suppression of GUS activity was greatest during mid to late stages of seed development, when expression of the alpha' promoter is high. These results indicate that suppression of GUS activity is due to expression of the antisense gene.

Multiple nuclear factors interact with upstream sequences of differentially regulated beta-conglycinin genes.

The expression of the alpha' and beta subunit genes of beta-conglycinin is differentially regulated during soybean embryo development. Although both are expressed solely in developing seeds during mid to late stages of embryo development, the alpha' subunit is expressed more highly on a per gene basis, and alpha' subunit mRNA begins to accumulate three to five days earlier than beta subunit mRNA. In cultured cotyledons, beta subunit gene(s) respond to changes in methionine or abscisic acid levels, whereas expression of the alpha' subunit gene(s) is unaffected by these changes. To investigate the mechanisms by which these genes are transcriptionally regulated, we examined the interactions of nuclear proteins with upstream sequences from the alpha' and beta subunit genes. Four distinct DNA binding factors were identified in nuclear extracts from developing soybean seeds. These factors are termed Soybean Embryo Factors (SEF) 1 through 4. SEF binding sites are distributed non-uniformly between the alpha' and beta subunit genes, and the amount of protein binding is modulated over the course of embryo development. DNA footprinting revealed the sequences recognized by three of these factors. Factors which behave in a manner similar to that of SEF3 were also identified in nuclear extracts from developing tobacco and sunflower seeds.

Nuclear factors interact with a soybean beta-conglycinin enhancer.

Upstream sequences of the gene encoding the alpha' subunit of beta-conglycinin were analyzed for interactions with nuclear proteins from immature soybean seeds. Two factors were identified that interact with specific sequence elements within 257 base pairs 5' of the transcription start site. One factor, SEF 3, binds exclusively to a region composed of two elements located at -183 to -169 base pairs and -153 to -134 base pairs relative to the start of transcription. Each of these sites includes the hexanucleotide sequence AACCCA, which may serve as a primary recognition sequence. During seed development, SEF 3 binding activity was found to increase in soybean embryos during the time of beta-conglycinin synthesis and to decrease as seeds neared maturity. The position of the SEF 3 binding sequence corresponds with a previously reported seed-specific enhancer region, and it seems likely that this factor may act as a positive regulator of transcription of the beta-conglycinin, alpha' subunit gene in developing soybean seeds. The second factor, SEF 4, also binds within the -257 to -77 region but also interacts with sites located further upstream.