Bruce J. Dolnick

Altered folate-binding protein mRNA stability in KB cells grown in folate-deficient medium

Folate-binding protein (FBP), a high-affinity folate receptor, is responsible for cellular accumulation of folate and folate analogs such as methotrexate in human KB (nasopharyngeal carcinoma) cells. Both FBP and FBP mRNA increase 3- to 5-fold when KB cells are grown in folate-deficient (less than 10 nM folate) medium (KB-FD), compared with growth in standard folate-replete medium containing at least 2 microM folate (KB-FR). The possible mechanisms of enhanced FBP gene expression in KB-FD were examined in this study. Southern blot analysis revealed no significant change in the FBP gene organization or copy number in the KB-FD DNA. While hypomethylation of the FBP gene was observed in KB-FD DNA, relative to KB-FR DNA, exposure of KB-FR to the DNA methylation inhibitors did not result in elevated FBP mRNA levels. The transcriptional rate of the FBP gene was the same in KB-FR and KB-FD. RNA half-life studies indicated that the half-life of FBP mRNA in KB-FD was increased approximately 2.5-fold, compared with KB-FR. Thus, the increase in the steady-state levels of FBP mRNA in KB-FD can be attributed partly to increased FBP mRNA stability.

Antisense agents in pharmacology

This commentary is designed to evaluate the applications and potential applications of antisense agents for the pharmacologist. The issues of mechanism of the biologic response mediated by antisense oligodeoxyribonucleotides (ODNs*) and evaluation of an antisense response are discussed. In addition, some practical applications are presented with the intent of suggesting the best means whereby pharmacologists may exploit current technology for their own interests

A Novel Function for the rTS gene

The rTS gene codes for a naturally occurring antisense RNA to thymidylate synthase (TS) mRNA and two proteins (rTSa and rTSβ). The role of the major protein product of rTS, rTβ has been linked to alterations in TS protein expression, but the precise function of rTSβ is unknown. In this report we demonstrate that increased expression of rTSβ is associated with the decrease in TS protein expression due to production of novel, diffusible signal molecules. These signal molecules are produced more abundantly when rTSβ amounts are elevated. This hypothesis is supported by the demonstration that the rTSβ-overproducing cell line H630-1 can down-regulate TS protein in other cells without direct cellular contact. These cells are shown to secrete significant amounts of lipophilic metabolites derived from methionine, in contrast to cells that do not overproduce rTSβ. In support of the hypothesis that rTSβ is essential for the generation of these compounds, we demonstrate that rTSβ can catalyze the transfer of the carboxyl carbon of methionine from S-adenosylmethionine to a lipophilic acceptor molecule in vitro. We propose rTS is involved in regulation of TS through a novel methionine-based signaling pathway.

Enhancement of 5-fluorouracil sensitivity by an rTS signaling mimic in H630 colon cancer cells.

The rTSbeta protein has been hypothesized to synthesize signaling molecules that can down-regulate thymidylate synthase. These molecules share biological and chemical properties with acyl-homoserine lactones (AHL), suggesting some AHLs might act as rTS signaling mimics and down-regulate thymidylate synthase. We have determined that the AHL, 3-oxododecanoyl homoserine lactone (3-oxo-C12-(L)-HSL) can down-regulate thymidylate synthase protein at 10 micromol/L and reduce H630 (human colorectal cancer) growth by 50% at 23 micromol/L (IC50) in cell culture. At its IC50 concentration, 3-oxo-C12-(L)-HSL reduces the apparent IC50 of 5-fluorouracil (5-FU) from 1 micromol/L to 80 nmol/L (12-fold) in a colony formation assay. 3-Oxo-C12-(L)-HSL enhances the activity of 5-fluorodeoxyuridine, tomudex, and taxol but not the activity of 5-fluorouridine, methotrexate or Adriamycin. The unexpected interaction with taxol probably results from effects of the AHL on tubulin expression. Differences in taxol sensitivity, tubulin, and cellular morphology between H630 and the thymidylate synthase and rTSbeta-overproducing, 5-FU-resistant H630-1 cell line as determined by colony formation assays, Western analysis of one-dimensional and two-dimensional gels, and photomicroscopy confirm that cytoskeletal changes are induced by the AHL or by rTS signaling. Isozyme differences in thymidylate synthase and rTSbeta also exist in the two cell lines. Phosphorylation of rTSbeta amino acid S121 is shown to occur and is decreased at least 10-fold in the drug-resistant cells. The data presented provide support for further investigations of rTS signaling mimics as enhancers to thymidylate synthase-directed chemotherapy, evidence that the phosphorylation state of rTSbeta may be a marker for 5-FU resistance and a previously unrealized relationship between rTS signaling and the cytoskeleton.

rTS gene expression is associated with altered cell sensitivity to thymidylate synthase inhibitors

rTS is a recently discovered gene, phylogenetically conserved and found to be expressed in a wide variety of cell lines. rTS has also been found to be overexpressed in two cell lines resistant to FU and to MTX. The MTX-resistant cell line was found to have a high degree of cross resistance to several TS inhibitors. An apparent paradox to this correlation of rTS overexpression and resistance to TS inhibitors is the observation that expression of transfected rTS alpha results in enhanced sensitivity of cells to the TS inhibitor prodrug TFT and a modest increase in resistance to FUdR. Since immunoprecipitation of TS leads to the co-immunoprecipitation of two proteins within the expected molecular weight range of the two rTS proteins, it may be that both proteins bind to TS in vivo and modify its activity. Preliminary data substantiate this conclusion. It is conceivable that the ratio of the two rTS proteins associated with TS in vivo may differentially alter TS activity depending upon their stoichiometry or possibly posttranslational modification. Thus it may be possible for rTS to confer greater sensitivity to one pyrimidine analog (e.g., TFT) which is a product analog but to increase resistance or have a minor effect on a substrate analog (e.g., FdUMP) by stabilizing different conformations of TS. The structure of the rTS proteins suggests they are expected to have catalytic activity which involves proton abstraction from an alpha-carbon of a carboxyl group. Whether this enzyme activity is functional and related to pyrimidine metabolism awaits further study.

A simplified synthesis of acridine and/or lipid containing oligodeoxynucleotides

Abstract A simplified method has been developed for the synthesis of acridine and/or lipid containing oligodeoxynucleotides using a commercially available resin and reagents.

Recent advances in the study of rTS proteins. rTS expression during growth and in response to thymidylate synthase inhibitors in human tumor cells.

The rTS proteins have now been shown to be expressed in a variety of cell lines, with expression of rTS beta being found elevated in three cell lines which are resistant to TS inhibitors (3, 4) (Figure 1). In one of these cell lines (K562 B1A), the cells were selected for resistance to MTX, which has a primary site of action on DHFR, but was found to be cross-resistant to FUdR (4). The other two cell lines were selected for resistance to either 5-fluorouracil (H630-1) or a combination of ZD1694 and FU. In each case, elevation of rTS beta appears to be a selected response to thymidylate stress. In HCT-8 and HCT-8/DF2 cells, treatment of cells for a short period of time (2 hr) resulted in the elevation of rTS beta levels, again suggestive that expression of rTS beta is a response to thymidylate stress. rTS beta appears to be regulated with cell growth, its levels increasing at mid-log and at late-log/saturation phase in H630 and H630-1 cells (Fig. 2), and increasing with late-log in several other cell lines as well (Fig. 3). The increase in rTS beta is suggestive of a cellular function associated with a state where growth is no longer desirable, reminiscent of the starvation-sensing protein homolog RSPA in E. coli (22). While this relationship would not explain the spike in rTS beta levels in mid-log H630 and H630-1 cells, it does make sense if the rTS proteins (particularly rTS beta) are involved in down-regulating thymidylate biosynthesis. The potential mechanism of this down-regulation may be speculated to be the catabolism of some precursor for thymidylate biosynthesis or some direct effect upon TS through modulation by some other ligand, either a metabolite or another protein. Studies on the expression of rTS proteins in clinical specimens indicate that rTS beta is expressed at high levels in kidney and kidney tumor (Dolnick, unpublished results). Given the physiologic role of the kidney, high level expression of rTS in this organ is consistent with a role in a catabolic pathway. Since down-regulation of TS activity is expected to increase sensitivity to TS inhibitors, a role for rTS beta in directly down-regulating TS activity in the biochemical sense would seem unlikely. However, the manner of biochemical TS down-regulation may make a difference. In the TS- Cl/Cl cell line, there are two mutations in TS which likely reduce affinity for N-5,10-methylene tetrahydrofolates (23). This cell line is highly resistant to MTX, yet is still tumorigenic in vivo (24), and supplying the cells with high levels of exogenous folate can restore TS function (23). Thus in TS- Cl/Cl cells, the TS phenotype is conditionally dependent upon the presence of high levels of exogenous folate. This suggests that a role of rTS proteins as conditional down-regulators of TS, perhaps through modulating folate binding, may be possible. Two cell lines (K562 B1A and H630-1) that overproduce rTS beta have altered sensitivity to TS inhibitors that differ depending upon the nature of the inhibitor. The K562 B1A cell line was found to be approximately 2000-fold resistant to ZD1694 and BW1843U89 (120 hr exposures), but only three-fold resistant to AG331. The H630-1 cell line is approximately 30-fold resistant to BW1843U89 (120 hr exposure) and 40-fold resistant to ZD1694 (120 hr exposure), but only eight-fold resistant to AG331. Since K562 B1A cells overproduce rTS beta (2), but have no significant alterations in FPGS activity, the possibility that rTS may affect folate binding remains a hypothesis worth examining. The recent discovery that TS is a phosphoprotein and that it is nuclear as well as cytoplasmic (21) raises the possibility that the phosphorylation state of TS may regulate one of its cellular functions, and that the subcellular localization of this enzyme is regulated as well. Since rTS proteins have HSP with proteins that participate in kinase/phosphatase reactions, this also seems to be an avenue worthy of future investigation. (ABSTRACT TRUNCATED

Transient knockdown and overexpression reveal a developmental role for the zebrafish enosf1b gene

BackgroundDespite detailed in vivo knowledge of glycolytic enolases and many bacterial non-enolase members of the superfamily, little is known about the in vivo function of vertebrate non-enolase enolase superfamily members (ENOSF1s). Results of previous studies suggest involvement of the β splice form of ENOSF1 in breast and colon cancers. This study used the zebrafish (Danio rerio) as a vertebrate model of ENOSF1β function.ResultsWhole mount in situ hybridization (WISH) showed that zebrafish ENOSF1β (enosf1b) is zygotic and expressed ubiquitously through the first 24 hours post fertilization (hpf). After 24 hpf, enosf1b expression is restricted to the notochord. Embryos injected with enosf1b-EGFP mRNA grew slower than EGFP mRNA-injected embryos but caught up to the EGFP-injected embryos by 48 hpf. Embryos injected with ATG or exon 10 enosf1b mRNA-targeting morpholinos had kinked notochords, shortened anterior-posterior axes, and circulatory edema. WISH for ntl or pax2a expression showed that embryos injected with either morpholino have deformed notochord and pronephros. TUNEL staining revealed increased apoptosis in the peri-notochord region.ConclusionsThis study is the first report of ENOSF1 function in a vertebrate and shows that ENOSF1 is required for embryonic development. Increased apoptosis following enosf1b knockdown suggests a potential survival advantage for increased ENOSF1β expression in human cancers.

Subclonal heterogeneity of the multidrug resistance phenotype in a cell line expressing antisense MDR1 RNA

A multidrug resistant (MDR) cell line was transfected with an antisense MDR1 expression vector and transfectant clones were analyzed for reversion of the MDR phenotype. Only one of 10 antisense-expressing transfectants showed a reduction in drug resistance, MDR1 mRNA and P-glycoprotein. Observations made using rhodamine-123, a fluorescent substrate for P-glycoprotein, revealed that dye retention in individual cells was highly variable within this antisense-expressing clone. Subpopulations were established from the original clone based on differences in rhodamine-123 retention. Rhodamine-123 retention varied inversely with levels of P-glycoprotein and MDR1 mRNA. All subpopulations expressed similar levels of antisense MDR1 RNA yet had dramatic differences in MDR1 mRNA levels. Analysis of vector integration site restriction fragment length polymorphisms confirmed that all populations originated from the same transfectant clone. Nuclear run-on analysis indicated that themdr1 gene is transcribed at the same rate in all populations, suggesting that the reduction in MDR1 mRNA is mediated posttranscriptionally. Cells with the greatest reduction in MDR1 mRNA accumulate distinct antisense RNA transcripts in the nuclear RNA fraction, suggesting that antisense effectiveness in this system is associated with a nuclear event or process. These results reveal that antisense RNA activity is not necessarily distributed equally within a clonal populations.

Comparative genomic analysis reveals a novel mitochondrial isoform of human rTS protein and unusual phylogenetic distribution of the rTS gene

BackgroundThe rTS gene (ENOSF1), first identified in Homo sapiens as a gene complementary to the thymidylate synthase (TYMS) mRNA, is known to encode two protein isoforms, rTSα and rTSβ. The rTSβ isoform appears to be an enzyme responsible for the synthesis of signaling molecules involved in the down-regulation of thymidylate synthase, but the exact cellular functions of rTS genes are largely unknown.ResultsThrough comparative genomic sequence analysis, we predicted the existence of a novel protein isoform, rTS, which has a 27 residue longer N-terminus by virtue of utilizing an alternative start codon located upstream of the start codon in rTSβ. We observed that a similar extended N-terminus could be predicted in all rTS genes for which genomic sequences are available and the extended regions are conserved from bacteria to human. Therefore, we reasoned that the protein with the extended N-terminus might represent an ancestral form of the rTS protein. Sequence analysis strongly predicts a mitochondrial signal sequence in the extended N-terminal of human rTSγ, which is absent in rTSβ. We confirmed the existence of rTS in human mitochondria experimentally by demonstrating the presence of both rTSγ and rTSβ proteins in mitochondria isolated by subcellular fractionation. In addition, our comprehensive analysis of rTS orthologous sequences reveals an unusual phylogenetic distribution of this gene, which suggests the occurrence of one or more horizontal gene transfer events.ConclusionThe presence of two rTS isoforms in mitochondria suggests that the rTS signaling pathway may be active within mitochondria. Our report also presents an example of identifying novel protein isoforms and for improving gene annotation through comparative genomic analysis.