Zinc Finger Nucleases: Tailor-made for Gene Therapy

Genome editing with the use of zinc finger nucleases has been successfully applied to variety of a eukaryotic cells. Furthermore, the proof of concept for this approach has been extended to diverse animal models from Drosophila to mice. Engineered zinc finger nucleases are able to target specifically and manipulate disease-causing genes through site-specific double strand DNA breaks followed by non-homologous end joining or homologous recombination mechanisms. Consequently, this technology has considerable flexibility that can result in either a gain or loss of function of the targeted gene. In addition to this flexibility, gene therapy by zinc finger nucleases may enable persistent long term gene modification without continuous transfection- a potential advantage over RNA interference or direct gene inhibitors. With systemic viral delivery systems, this gene-editing approach corrected the mutant factor IX in models of mouse hemophilia. Moreover, phase I clinical trials have been initiated with zinc finger nucleases in patients with glioblastoma and HIV. Thus, this emerging field has significant promise as a therapeutic strategy for human genetic diseases, infectious diseases and oncology. In this article, we will review recent advances and potential risks in zinc finger nuclease gene therapy.

Selective modification of HK peptides enhances siRNA silencing of tumor targets in vivo

Our research has focused on systemic delivery of small interference RNA (siRNA) by branched peptides composed of histidine and lysine. After studying several histidine-lysine (HK) peptides, one four-branched peptide, H3K(+H)4b, with a predominant repeating pattern of -HHHK-, was found to be an effective carrier of siRNA. Although the unmodified H3K(+H)4b carrier of siRNA targeting an oncogene was previously shown to have promise in a tumor-bearing mouse model, we sought to develop a more effective HK carrier of siRNA in this study. Our primary goal was to determine whether different ligand (cyclic RGD)-pegylation patterns on the H3K(+H)4b peptide affect siRNA delivery in vitro and in vivo. We compared the unmodified H3K(+H)4b with two modified H3K(+H)4b peptides for their ability to deliver siRNA in a tumor-bearing mouse model; one modified HK peptide, (RGD-PEG)(4)-H3K(+H)4b, had four cyclic RGD-polyethylene glycol (cRGD-PEG) conjugates per molecule, whereas the other peptide, (RGD-PEG)-H3K(+H)4b, had one cRGD-PEG per molecule. Although the modified HK peptides by themselves did not form stable nanoplexes with siRNA, combination of a highly charged unmodified HK peptide, H2K4b, with either of the modified HK peptides did form stable siRNA nanoparticles. For in vitro experiments with MDA-MB-435 cells that expressed luciferase (Luc), the H3K(+H)4b siRNA nanoplexes targeting Luc decreased its activity by 90% compared with negligible downregulation by the modified H3K(+H)4b nanoplexes (P<0.01). In contrast, the two modified H3K(+H)4b siRNA nanoplexes administered intravenously were more effective than the H3K(+H)4b nanoplexes in silencing Luc in a tumor xenograft model. The Luc activity in tumor lysates of mice administered H3K(+H)4b, (RGD-PEG)-H3K(+H)4b and (RGD-PEG)(4)-H3K(+H)4b nanoplexes decreased by 18, 35 and 75%, respectively. Thus, the siRNA nanoplex incorporating the highly modified peptide, (RGD-PEG)(4)-H3K(+H)4b, was the most effective at silencing its target in vivo (P<0.01). These studies demonstrate that selectively modified HK polymers are promising candidates for targeting oncogenes with siRNA.

Peptide-based Antifungal Therapies against Emerging Infections

Acquired drug resistance to mycotic infections is rapidly emerging as a major medical problem. Opportunistic fungal infections create therapeutic challenges, particularly in high risk immunocompromised patients with AIDS, cancer, and those undergoing transplantation. Higher mortality and/or morbidity rates due to invasive mycosis have been increasing over the last 20 years, and in light of growing resistance to commonly used antibiotics, novel antifungal drugs and approaches are required. Currently there is considerable interest in antifungal peptides that are ubiquitous in plant and animal kingdoms. These small cationic peptides may have specific targets or may be multifunctional in their mechanism of action. On the basis of recent advances in protein engineering and solid phase syntheses, the utility and potential of selected peptides as efficient antifungal drugs with acceptable toxicity profiles are being realized. This review will discuss recent advances in peptide therapy for opportunistic fungal infections.

Systemic delivery of HK Raf-1 siRNA polyplexes inhibits MDA-MB-435 xenografts

Our past research has focused on identifying an effective carrier composed of histidine and lysine for delivery of nucleic acid into cells. For this purpose, we developed histidine-lysine-rich (HK) polymers with specific sequences and branching. We have found that branched HK polymers in complex with Raf-1 siRNA markedly decreased Raf-1 mRNA and induced apoptosis in cell lines in vitro. The primary focus of the present study was to determine an effective carrier to deliver siRNA systemically to tumor xenografts. After comparing HK:Raf-1 polyplexes for their in-vivo efficacy, we investigated in greater detail whether one of these polymers, H3K(+H)4b, in complex with Raf-1 siRNA, inhibited the growth of MDA-MB-435 xenografts. H3K(+H)4b is a four-branched HK peptide whose predominant repeating sequence within the terminal arm is -HHHK-. After the first tail-vein injection in a mouse model, there was a statistically significant reduction in tumor size between the H3K(+H)4b:Raf-1 siRNA-treated and the control groups (P<0.01). By the third injection, there was nearly a 50% reduction in the Raf-1 siRNA-treated group compared to the control siRNA-treated or -untreated group. Consistent with a significant effect of the HK:Raf-1 polyplex on the tumor, there were marked histological changes, increased apoptosis and fewer vessels in the Raf-1 siRNA-treated group. Raf-1 protein within the tumor was significantly decreased after treatment with the HK:Raf-1 siRNA polyplex compared to the control treatment groups. Despite the striking effect on the tumor by the HK Raf-1 siRNA, there was little evidence of toxicity in normal tissues with this therapy. By harnessing the ability to modify the amino-acid sequence and branching of HK polymers, we expect continued development of HK polymers as in-vivo carriers of siRNA.

Targeting tumor angiogenesis with gene therapy

A recent target of cancer gene therapy is tumor angiogenesis. An appealing feature of gene therapy targeting the tumor vasculature is that it is readily accessible, particularly when the carrier and its gene are administered systemically. Several gene-based viral and nonviral therapies that target tumor angiogenesis have demonstrated the "proof of principle" of antiangiogenic therapy in preclinical models. The utility of antiangiogenic gene therapy in a clinical setting will depend in large part on developing vectors with minimal toxicity and with increased in vivo transfection efficiency. In this review, we discuss the current status and future directions of antiangiogenic gene therapy.

Branched co-polymers of histidine and lysine are efficient carriers of plasmids

We previously determined that a linear co-polymer of histidine and lysine (HK) in combination with liposomes enhanced the transfection efficiency of cationic liposomes. In the current study, we designed a series of HK polymers with increased branching and/or histidine/lysine ratio to determine if either variable affects transfection efficiency. In the presence of liposomes, the branched polymer with the highest number of histidines, HHK4b, was the most effective at enhancing gene expression. Furthermore, when serum was added to the medium during transfection, the combination of HHK4b and liposomes as a gene-delivery vehicle increased luciferase expression 400-fold compared to liposomes alone. In contrast to linear HK polymers, the higher branched HHK polymers were effective carriers of plasmids in the absence of liposomes. Without liposomes, the HHK4b carrier enhanced luciferase expression 15-fold in comparison with the lesser branched HHK2b carrier and increased expression by 5-logs in comparison with the HHK or HK carrier. The interplay of several parameters including increased condensation of DNA, buffering of acidic endosomes and differential binding affinities of polymer with DNA have a role in the enhancement of transfection by the HK polymers. In addition to suggesting that branched HK polymers are promising gene-delivery vehicles, this study provides a framework for the development of more efficient peptide-bond-based polymers of histidine and lysine.

Co-polymer of histidine and lysine markedly enhances transfection efficiency of liposomes

Development of nonviral delivery systems is progressing toward a transfection efficiency sufficient to affect metabolic and neoplastic diseases in humans. Nevertheless, inadequate transfection efficiency of target cells with current nonviral systems still limits the utility of this therapy. In the current study, we have determined that a co-polymer of histidine and lysine (H-K) enhances the transfection efficiency of liposomes, a leading nonviral system. We found that in the absence of serum, the addition of this polymer increased transfection as much as 10-fold in comparison with the liposome:DNA complex alone. More impressively, the co-polymer in the presence of serum increased transfection efficiency up to 100-fold. Furthermore, in vivo expression of luciferase in a tumor increased 15-fold with the addition of H-K polymer to the liposome:plasmid DNA complexes. Without liposomes, the H-K polymer had little to no effect on transfection efficiency. We anticipate that further modifications of this co-polymer will yield molecules with both increased complexity and transfection efficiency.

Antiangiogenic Gene Therapy in Cancer

One of the most recent and exciting approaches in cancer gene therapy is the ability to target the developing blood supply of the tumor. An appealing feature of antiangiogenic gene therapy is that the tumor vasculature is a readily accessible target, particularly when the carrier and its gene are administered systemically. This is in contrast to several other gene therapy approaches in which the tumor vasculature represents a major obstacle to achieving high levels of transfection of the tumor cells. Several gene-based viral or non-viral therapies that target tumor angiogenesis have shown efficacy in pre-clinical models. Genes that encode antiangiogenic polypeptides such as angiostatin and endostatin have significantly inhibited tumor growth, inducing a microscopic dormant state. The products of these genes are thought to act extracellularly to inhibit angiogenesis. An alternative approach that investigators have used successfully in tumor-bearing mice is to target angiogenic growth factors or their receptors that are essential for tumor growth. Levels of angiogenic factors such as vascular endothelial growth factor (VEGF) have been reduced by either antisense methods or the use of genes encoding truncated angiogenic decoy receptors. Despite these promising findings of tumor reduction with antiangiogenic gene therapy, advances in the viral and/or non-viral delivery systems are essential for this therapy to have clinical utility. In this review, we will discuss the mechanisms of angiogenesis/antiangiogenesis, and the current status and future directions of antiangiogenic gene therapy.

Liposomes complexed to plasmids encoding angiostatin and endostatin inhibit breast cancer in nude mice

Gene therapy transfer of angiostatin and endostatin represents an alternative method of delivering angiogenic polypeptide inhibitors. We examined whether liposomes complexed to plasmids encoding angiostatin or endostatin inhibited angiogenesis and the growth of MDA-MB-435 tumors implanted in the mammary fat pads of nude mice. We determined that plasmids expressing angiostatin (PCI-Angio) or endostatin (PCI-Endo) effectively reduced angiogenesis using an in vivo Matrigel assay. We then investigated the efficacy of these plasmids in reducing the size of tumors implanted in the mammary fat pad of nude mice. Both PCI-Angio and PCI-Endo significantly reduced tumor size when injected intratumorally (P < 0.05). Compared to the untreated control group, the mice treated with PCI-Angio and PCI-Endo exhibited a reduction in tumor size of 36% and 49%, respectively. In addition, we found that i.v. injections of liposomes complexed to PCI-Endo reduced tumor growth in the nude mice by nearly 40% when compared to either empty vector (PCI) or untreated controls (P < 0.05). These findings provide a basis for the further development of nonviral delivery of antiangiogenic genes.

Systemic gene therapy with p53 inhibits breast cancer: recent advances and therapeutic implications

Development of gene therapy technologies is approaching clinical realization for the treatment of neoplastic diseases. The use of tumor suppressor genes has been one useful strategy in gene therapy. Modifications and development of vectors as well as increased knowledge of the anti-tumor mechanisms of the p53 will play a significant role in the further advancement of this therapy. Currently, several laboratories have demonstrated that intratumoral injection of a virus carrying the p53 gene decreases tumor size in pre-clinical and clinical studies. Our lab has focused on a tumor-bearing mouse model in which intravenous delivery of liposome: p53 complexes decreases tumor growth. Although a high transfection efficiency of the tumor was thought to be necessary for gene therapy to exhibit anti-tumor activity with tumor suppressor genes, marked inhibition of the tumor occurs even with a low transfection efficiency. p53 may exhibit its bystander anti-tumor effect, at least in part, through an antiangiogenic effect. We believe that understanding the mechanism by which the p53 tumor suppressor gene inhibits tumor growth will lead to improvement in cancer therapy.

In vivo gene therapy with a cationic polymer markedly enhances the antitumor activity of antiangiogenic genes

A cationic polymer, Superfect, when complexed to the therapeutic genes, p53 and a TSP fragment, displays a much greater antitumor activity compared to cationic liposomes. At the dosages used, this polymer did not demonstrate any nonspecific antitumor effects in contrast to the liposome carriers. These in vivo findings should further stimulate the development of carrier polymers as well as expedite the evaluation of several antiangiogenic genes.

Gene therapy with p53 and a fragment of thrombospondin I inhibits human breast cancer in vivo

We recently reported that a p53 encoding plasmid (BAP-p53) complexed to liposomes administered intravenously markedly attenuates the growth of a malignant human breast tumor. We now have found that systemically delivered liposomes complexed to a plasmid expressing an established antiangiogenic peptide of thrombospondin I (BAP-TSPf) decreased the growth of MDA-MB-435 tumors compared to controls in nude mice. Compared to BAP-p53, the BAP-TSPf group had a similar antitumor efficacy. More importantly, liposomes complexed with BAP-TSPf and BAP-p53 synergistically decreased the growth of MDA-MB-435 tumors when compared to either BAP-p53 or BAP-TSPf alone. Furthermore, we also determined that the combination therapy of p53 and TSPf inhibited endothelial cells in vitro more than either p53 or TSPf alone. There was also a significant decrease of the blood vessel density in the combination p53 and TSPf treatment group compared to the control groups. These results suggest that liposomes complexed to a tumor suppressor and antiangiogenic genes may be effective in treating metastatic tumors.

Parenteral gene therapy with p53 inhibits human breast tumors in vivo through a bystander mechanism without evidence of toxicity

Mutations of the p53 tumor suppressor gene are the most frequently observed genetic lesion in human cancer. Previously, we found that multiple intravenous injections of a liposome:p53 complex inhibited the growth of a malignant human breast cancer cell line that was implanted into nude mice. In the present study, we evaluated the toxicity of the liposome:p53 complex and the mechanism of this in vivo treatment in reducing tumor growth. Intravenously delivered liposome:p53 complex at dosages sufficient to inhibit human breast cancer in nude mice showed no evidence of toxicity. Clinical chemistries, complete blood counts, and histopathologic examination of various organs from the p53-treated groups did not demonstrate any difference from the control groups. To elucidate the mechanism by which the liposome:p53 complex inhibits cancer, the transfection efficiency of a liposome:chloramphenicol acetyltransferase (CAT) complex into the tumor was determined. Interestingly, less than 5% of the tumor was transfected with a liposome:CAT complex. A mechanism that could account for p53 reduction of tumor size and a low transfection efficiency is inhibition of angiogenesis. After one treatment, we found that the liposome:p53 complex reduced the number of blood vessels in the p53-treated group by approximately 60% compared to the control group (p < 0.001). The close correlation between the antitumor effect of p53 and the reduction of blood vessel density in the tumor suggests that p53 effects are mediated, at least in part, by an antiangiogenesis mechanism.

Systemic gene therapy with p53 reduces growth and metastases of a malignant human breast cancer in nude mice

We report on an in vivo delivery system that attenuates the growth, in nude mice, of a malignant human breast cancer cell line containing a p53 mutation. Nude mice, inoculated with breast carcinoma cells, were injected every 10-12 days with a liposome-p53 complex via the tail vein. A significant reduction of greater than 60% in primary tumor volume was observed as compared to the control groups. Furthermore, when individual growth patterns of the tumors were assessed, we found that primary tumor size regressed in the majority of p53-treated animals (8/15), whereas only one tumor in the control groups (1/22) regressed. The eight tumors that regressed with the liposome-p53 complex showed no evidence of relapse for 1 month after the cessation of treatment. We also determined that the administration of the liposome-p53 complex reduced the incidence of metastases. The MDA-MB-435 tumor cells, transduced with the lacZ gene, facilitated quantitation of beta-galactosidase activity and tumor burden in the lungs. The number of metastatic cells in the lung was significantly lower in the p53-treated group (0.53 +/- 0.43 x 10(6), p < 0.01) than in either the vector-treated (8.1 +/- 3.7 x 10(6)) or untreated control groups (15.8 +/- 5.9 x 10(6)). Thus, systemic administration of the liposome-p53 complex reduced not only the size of the primary tumors but, more importantly, prevented the relapse and metastases of these tumors.

Analysis of the binding of 3,3',5-triiodo-L-thyronine and its analogues to mutant human beta 1 thyroid hormone receptors: a model of the hormone binding site

To understand the nature of the thyroid hormone binding site, we characterized the binding of 3,3',5-triiodo-L-thyronine (T3) and its analogues to eight naturally occurring mutated human beta 1 thyroid hormone receptors (h-TR beta 1). The mutant receptors were derived from patients with the syndrome of generalized thyroid hormone resistance, and each has a point mutation in the hormone binding domain (KT, R338W; TP, L450H; IR, D322H; NN, G347E; AH, P453H; OK, M442V; RL, F459C; and ED, A317T). Compared to the wild-type h-TR beta 1, binding of T3 was reduced by as much as 97% for the mutants. The order of binding affinity of wild-type h-TR beta 1 to the analogues is T3 > D-T3 > L-thyroxine > 3,5-diiodo-L-thyronine > 3,3',5'-triiodo-L-thyronine. The mutant receptors showed essentially the same order of reduced affinities for the analogues, but the amounts of the reductions varied in each case. These results suggest specific local interactions (interplay) of analogues with the mutated residues in the receptors. On the basis of these data and a putative structure of the hormone binding domains as an eight-stranded alpha/beta barrel, we propose the location of the hormone in the binding site of h-TR beta 1. Ionic bonds anchor the hormone's alanine side chain to loop 4 of the 8-fold alpha/beta barrel. The phenyl ring lies across the amino-terminal face of the domain with the phenoxy ring pointing downward into the barrel interacting with beta-strand 8 on the opposite side.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential expression of mutant and normal beta T3 receptor alleles in kindreds with generalized resistance to thyroid hormone

Thyroid hormone resistance (THR) is primarily an autosomal dominant inherited disease characterized by resistance of pituitary and peripheral tissues to the action of thyroid hormone. We investigated whether the heterogeneous phenotypic features that occur not only among kindreds but also within the same kindred might be due to the expression of differing ratios of mutant and normal receptors in tissues. Using an allele-specific primer extension method, we determined the relative expression of normal and mutant mRNAs from the fibroblasts of affected and unaffected members of two kindreds with TRH: A-H and N-N. While two affected members of A-H, as expected, had nearly equal amounts of normal and mutant hTR beta mRNA, two other members had mutant mRNA levels that accounted for at least 70% of the hTR beta mRNA. Phenotypic variability within and between kindreds with generalized resistance to thyroid hormone GRTH may be due to this differential expression of the mutant and wild type mRNA. Furthermore, when several clinical parameters of THR were compared in several affected members from two kindreds with GRTH, we found that two cases in one kindred exhibited a high mutant-to-normal hTR beta ratio and had considerably more bone resistance during their development. In certain kindreds with THR, differing ratios of normal and mutant hTR receptors may be age and growth related and may account for the reported attenuation of phenotypic symptoms with age.

Attention deficit-hyperactivity disorder in people with generalized resistance to thyroid hormone

BACKGROUND

Attention deficit-hyperactivity disorder is a well-recognized psychiatric disorder of childhood. Its cause is unknown, but there is evidence of a familial predisposition. Symptoms suggestive of this disorder have been reported in subjects with generalized resistance to thyroid hormone, a disease caused by mutations in the thyroid receptor-beta gene and characterized by reduced responsiveness of peripheral and pituitary tissues to the actions of thyroid hormone. We systematically evaluated the presence and severity of attention deficit-hyperactivity disorder in 18 families with a history of generalized resistance to thyroid hormone.

METHODS

We studied 49 affected and 55 unaffected family members; 52 were adults, and 52 were children. All subjects were evaluated with structured psychiatric questionnaires by interviewers who were unaware of the medical diagnosis. The number of symptoms of attention deficit-hyperactivity disorder was calculated for each subject.

RESULTS

Among the adults, 11 of 22 subjects with generalized resistance to thyroid hormone (50 percent) and 2 of 30 unaffected subjects (7 percent) had met the criteria for attention deficit-hyperactivity disorder as children (P < 0.001). Among the children, 19 of 27 subjects resistant to thyroid hormone (70 percent) and 5 of 25 unaffected subjects (20 percent) met the criteria for the disorder (P < 0.001). The odds of having attention deficit-hyperactivity disorder were 3.2 times higher for affected male subjects than for affected female subjects and were 2.7 times higher for unaffected male subjects than for unaffected female subjects. The mean symptom score was 2.5 times higher in the affected group than in the unaffected group (7.0 vs. 2.8, P < 0.001). The frequency of other psychiatric diagnoses was similar in the two groups.

CONCLUSIONS

In our study sample, attention deficit-hyperactivity disorder is strongly associated with generalized resistance to thyroid hormone.

Identification of a novel mutation in the gene encoding the beta-triiodothyronine receptor in a patient with apparent selective pituitary resistance to thyroid hormone

OBJECTIVE

We investigated whether the first patient (L-F3) reported as having selective pituitary resistance had a mutation in the hTR beta gene. We compared the clinical parameters of this case with those of patients with generalized resistance to thyroid hormone.

DESIGN

The patient, L-F3, was part of a study at the NIH to identify mutations by sequencing the hTR beta gene in kindreds with thyroid hormone resistance. The clinical data of L-F3 as well as patients with generalized resistance to thyroid hormone were compared and analysed retrospectively.

MEASUREMENT

We amplified by the polymerase chain reaction and then sequenced exons 5 to 10 of the hTR beta gene in L-F3 and a normal control. Upon finding the mutation in L-F3, we measured the affinity constant of this mutated hTR beta receptor. Criteria developed previously were used to assess tissue responsiveness to thyroid hormone of L-F3.

RESULTS

We identified a C to T transition at base 1297 in codon 333 of the hTR beta gene in the first patient (L-F3) reported as having apparent selective pituitary resistance. This base substitution resulted in more than a four-fold decrease in T3-binding affinity for the hTR beta 1 receptor. The mutation of L-F3 occurred in the dimerization domain of exon 9, a region where the majority of mutations of kindreds with generalized thyroid hormone resistance have been found. Furthermore, the nucleotide substitution at base 1297 found in the apparent selective pituitary resistant case, L-F3, was the same as in an unrelated patient (K-T3) with generalized resistance to thyroid hormone. As a result, we compared the clinical parameters of both patients and found that they had similar patterns of resistance in several tissues. Besides the bone resistance present in both kindreds, the apparent selective pituitary resistance case also had liver and neuromuscular resistance.

CONCLUSIONS

These findings suggest that apparent selective pituitary resistance and generalized resistance to thyroid hormone are not qualitatively different syndromes. Nevertheless, identification of selective pituitary resistance is a useful clinical distinction since such patients with clinical and biochemical features of hyperthyroidism appear to benefit from reduction in serum thyroid hormone concentrations. In contrast, patients with more conventional forms of thyroid hormone resistance require no treatment or may benefit from increased concentrations of thyroid hormone.

Thyrotropin-secreting pituitary carcinoma

Pituitary tumors rarely metastasize outside the central nervous system. Of the more than 100 reported TSH-secreting adenomas, we now describe the first carcinoma. A 40-yr-old woman had transsphenoidal surgery for a large TSH-secreting pituitary adenoma in 1984. She had increased thyroid hormone levels with a TSH that varied from 16-31 microU/mL, and an unusually high alpha-subunit that ranged from 125-150 ng/mL. Because of residual tumor, she had a left craniotomy in 1985 followed by radiation. Despite these therapies, she had a residual tumor that remained stable until January 1989 when her tumor nearly doubled in size. She received radiation therapy and octreotide with marked diminution of the tumor and clinical improvement. In August 1989, she presented with leg weakness, and magnetic resonance imaging revealed a large sacral mass. A biopsy confirmed that the sacral mass was a metastasis from the pituitary tumor. Due to additional metastases in the lung, she received 5-fluorouracil, cytoxan, and adriamycin, with marked decrease in her lesions. Further substantiation of the metastatic pituitary tumor was made when the patient returned in December 1989 with a pleural effusion containing pituitary tumor cells. Of all the reported cases of TSH-secreting adenomas, this case had the highest alpha-subunit portending future metastases. Furthermore, the apparent response to octreotide and response to chemotherapy are encouraging and suggest that new therapies should be explored. Finally, since TSH-secreting adenomas tend to be more invasive than other pituitary tumors, this case underscores the need for early diagnosis and aggressive treatment of these tumors.

The proto-oncogenes c-fos and c-jun modulate thyroid hormone inhibition of human thyrotropin beta subunit gene expression in opposite directions

The sequence from -1 to +6 bp in the hTSH beta gene contains overlapping putative thyroid hormone and AP-1 response elements. We demonstrate interaction between the AP-1 constituents c-fos and c-jun and thyroid hormone receptor in this region by transient transfection experiments using a -125 to +37 bp hTSH beta fragment. T3 inhibition was completely abolished by c-jun, but increased threefold by c-fos. A single transversion mutation at +2 bp restored T3 inhibition in the presence of c-jun and markedly reduced binding of purified c-jun by gel mobility shift assay. Thus, c-fos and c-jun influence T3 inhibition of hTSH beta expression in opposite directions acting through a response element shared with thyroid hormone receptor. Control of the relative cellular levels of these two proto-oncogenes may play a major role in modulating thyroid hormone inhibitory responses.

Correlations of language abnormalities with localization of mutations in the beta-thyroid hormone receptor in 13 kindreds with generalized resistance to thyroid hormone: identification of four new mutations

Generalized resistance to thyroid hormone is an inherited disease characterized by unresponsiveness of pituitary and peripheral tissues to thyroid hormone. Genetic analysis of several kindreds linked this syndrome to the gene for the beta-form of the thyroid hormone receptor, and this led to the subsequent identification of various mutations in the ligand-binding domain of this receptor. In this region we now have found 4 new point mutations with reduced T3-binding affinities from separate kindreds by direct sequencing of polymerase chain reaction products. Similar to previously studied kindreds, the reduction in T3 binding of these four kindreds ranged from 2.5- to 5-fold, indicating that these are not neutral polymorphisms. Furthermore, the pattern of inheritance of these 4 kindreds is familial in 2, sporadic in 1, and unknown in 1. To date, 20 distinct mutations have been identified, of which 18 are clustered in 2 distinct topographical regions: 11 are within the tau i/dimerization subdomains of exon 9, and 7 are within the L2 subdomain of exon 10. The 4 newly identified mutations coupled to the 9 mutations our laboratory has previously identified provide new insights into the clinical aspects of generalized resistance to thyroid hormone. Kindreds with mutations in exon 9 compared with those in exon 10 have significantly more problems in language development, as manifested by articulation problems and/or wide discrepancies in verbal and performance IQs. Interestingly, marked variability in language deficiency as well as other clinical patterns were seen not only between kindreds but also within a kindred. Further identification and clinical correlations of new mutations will continue to enhance our understanding of the structure/function relationships and physiological role of the human thyroid hormone receptor.

Characterization of seven novel mutations of the c-erbA beta gene in unrelated kindreds with generalized thyroid hormone resistance. Evidence for two "hot spot" regions of the ligand binding domain

Genetic analysis in our laboratory of families with generalized thyroid hormone resistance (GTHR) has demonstrated tight linkage with a locus, c-erbA beta, encoding a nuclear T3 receptor. Three point mutations and two deletions in this locus have previously been reported in affected individuals in unrelated families as potential molecular bases for this disorder. In the present study, we have used direct sequencing of polymerase chain reaction-amplified exons of the c-erbA beta gene to rapidly identify novel point mutations from seven previously uncharacterized kindreds with GTHR. Six single base substitutions and one single base insertion were identified and found to be clustered in two regions of exons 9 and 10 in the ligand binding domain of the receptor: in the distal ligand-binding subdomain L2 and across the juncture of the taui and dimerization subdomains. Reduction of T3-binding affinity in each of four mutations tested as well as segregation of all mutations to clinically affected individuals strongly supports the hypothesis that these changes are the cause of GTHR in these kindreds. In view of the diversity of clinical phenotypes manifested, the distinct topographic clustering of the mutations provides an invaluable genetic tool for the molecular dissection of thyroid receptor function.

Structural analogues of pyrroline 5-carboxylate specifically inhibit its uptake into cells

Pyrroline 5-carboxylate, a naturally occurring intermediate, is a potent activator of redox-dependent metabolic pathways. The effect of pyrroline 5-carboxylate is due, at least in part, to the special mechanism mediating its entry into cells. Using Chinese hamster ovary cells we recently characterized the cellular uptake of pyrroline 5-carboxylate as a process transferring oxidizing potential pari passu with cell entry, a process consistent with group translocation. We sought to identify specific inhibitors to probe this unique uptake mechanism, to blockade the metabolic effects of pyrroline 5-carboxylate, and to provide strategies to identify the putative carrier protein. Because pyrroline 5-carboxylate, a ring structure with a tertiary nitrogen, is in spontaneous equilibrium with glutamic-gamma-semialdehyde, an open-chain structure, we tested analogues of both. Most open-chain aldehydes at 10 mM had little effect on the uptake of pyrroline 5-carboxylate. Although succinic semialdehyde did inhibit, its effect was nonspecific in that the uptake of alpha(methylamino) isobutyric acid was inhibited as much as the uptake of pyrroline 5-carboxylate. In contrast, pyrroline 2-carboxylate and other cyclic compounds with tertiary nitrogens, e.g., pyridines, were specific inhibitors of pyrroline 5-carboxylate uptake. Respective potencies of pyridine derivatives depended on the nature and location of constituent groups. Kinetics studies showed that these inhibitors were competitive with pyrroline 5-carboxylate and the most potent inhibitor, 2,6-pyridinedicarboxaldehyde, exhibited a K12 of 0.27 +/- 0.05 mM.(ABSTRACT TRUNCATED AT 250 WORDS)

The uptake of pyrroline 5-carboxylate. Group translocation mediating the transfer of reducing-oxidizing potential

The cellular uptake of pyrroline 5-carboxylate (P5C) is of interest because this nutritionally responsive constituent of human plasma can mediate the transfer of oxidizing potential into cells and stimulate the production of phosphoribosyl pyrophosphate. Using a cloned line of Chinese hamster ovary cells, we found that the uptake of P5C was saturable, temperature-dependent, and sensitive to metabolic inhibitors. Furthermore, this uptake of P5C exhibited unusual features. It was independent of sodium ion and had a pH optimum of 6.4. The kinetics characteristics of P5C uptake included an apparent Km of 0.46 +/- 0.04 mM and a Vmax of 19.6 +/- 1.8 nmol/min/mg. Although the Vmax for P5C was comparable to those for certain other amino acids, e.g. leucine, it was significantly higher than that for alpha-methylaminoisobutyric acid in these cells. Importantly, there was no interaction between these amino acids and the uptake mechanism for P5C. Twenty naturally occurring amino acids, each at a concentration of 5 mM, were without effect on the uptake of P5C. Interestingly, the uptake mechanism for P5C is unusual in that it is linked to the transfer of reducing-oxidizing potential. Over wide ranges of P5C concentration and duration of incubation, P5C entry is coupled to its conversion to proline and the concomitant oxidation of reduced pyridine nucleotide with stimulation of the pentose phosphate shunt. In fact, no free P5C derived from the medium could be detected in cells. Our interpretation of these findings is that P5C uptake occurs by its own unique mechanism, a group translocation that mediates the transfer of reducing-oxidizing potential.