Intracellular retention of mutant gonadotropin receptors results in loss of hormone binding activity of the follitropin receptor but not of the lutropin/choriogonadotropin receptor

It has recently been reported that Asp 397 of the rat lutropin/ choriogonadotropin receptor (rLHR) may be involved in transducing the signal from hormone binding to the stimulation of cAMP production. We examined the analogous region in the rat follitropin receptor (rFSHR) by substituting the Asp at position 404 (D404) of the rFSHR with either Glu (D404E), Ala (D404A), or Lys (D404K). Both in intact 293 cells and in detergent-solubilized extracts of 293 cells transiently transfected with the rFSHR constructs, only the wild type rFSHR exhibited detectable binding activity. Although the D404-substituted rFSHR mutants were visible on Western blots, in contrast to the wild type rFSHR which is present on Western blots as both mature and immature forms, only a single band comigrating with immature receptor was observed for the mutants. Furthermore, these mutants were sensitive to endoglycosidase H (Endo H), thus indicating that the mutant receptor proteins were retained intracellularly in the endoplasmic reticulum. To test whether the lack of binding of the D404-substituted rFSHR mutants was due to a perturbation of a binding site or to the intracellular retention of the mutants, a truncated rFSHR(t637) mutant, containing a cytoplasmic truncation that should not directly affect FSH binding, was examined. As with the D404-substitution mutants, rFSHR(t637) was stably expressed but sensitive to Endo H. Significantly, detergent-soluble extracts of cells expressing rFSHR(t637) were unable to bind FSH. From these results, we conclude that substitution of D404 of the rFSHR prevents hormone binding as a result of the intracellular retention of the mutants in the endoplasmic reticulum presumably in an incompletely folded state, as opposed to disruption of a hormone-binding site at D404. Comparable rLHR substitution (D397K) and truncation (t616) mutants were constructed and used to transfect 293 cells. For both rLHR(D397K) and rLHR(t616), human CG (hCG) binding to intact cells was not detectable, but high affinity hCG binding was observed in detergent-soluble extracts of the cells. Therefore, the rLHR differs from the rFSHR in that mutants of the rLHR that are retained in the endoplasmic reticulum have already been folded correctly and can bind hCG with high affinity as long as a hormone-binding site has not been perturbed by the mutation. In contrast, mutants of the rFSHR that are retained in the endoplasmic reticulum have not yet folded into a conformation that can bind hormone. This suggests a difference in the temporal pattern of folding between the two structurally related gonadotropin receptors. Our studies also demonstrate how mutagenesis studies of the rFSHR must be interpreted with caution, as FSHR mutants that are expressed but are retained intracellularly will most likely not be able to bind FSH even when a hormone-binding site has not been altered.     

Mitochondrial genome damage associated with cigarette smoking

We have investigated the level of mitochondrial DNA (mtDNA) damage and deletions in bronchoalveolar lavage tissues from smokers and nonsmokers using quantitative, extra-long PCR and a "common" mtDNA deletion assay. Smokers had 5.6 times the level of mtDNA damage, 2.6 times the damage at a nuclear locus (beta-globin gene cluster), and almost 7 times the level of a 4.9-kb mtDNA deletion compared to nonsmokers, although the latter increase was not significant. Although both genomes (mitochondrial and nuclear) showed significantly increased levels of DNA damage in smokers (mtDNA P = 0.00072; beta-globin P = 0.0056), the relative differences were greatest in the mtDNA. Damage to the mtDNA may inhibit oxidative phosphorylation and, therefore, potentially cause or contribute to chronic lung disease and cancer. Consequently, the mtDNA may be a sensitive biomarker for environmentally induced genetic damage and mutation.     

Product release is the major contributor to kcat for the hepatitis C virus helicase-catalyzed strand separation of short duplex DNA

Hepatitis C virus (HCV) helicase catalyzes the ATP-dependent strand separation of duplex RNA and DNA containing a 3' single-stranded tail. Equilibrium and velocity sedimentation centrifugation experiments demonstrated that the enzyme was monomeric in the presence of DNA and ATP analogues. Steady-state and pre-steady-state kinetics for helicase activity were monitored by the fluorescence changes associated with strand separation of F21:HF31 that was formed from a 5'-hexachlorofluorescein-tagged 31-mer (HF31) and a complementary 3'-fluorescein-tagged 21-mer (F21). kcat for this reaction was 0.12 s-1. The fluorescence change associated with strand separation of F21:HF31 by excess enzyme and ATP was a biphasic process. The time course of the early phase (duplex unwinding) suggested only a few base pairs ( approximately 2) were disrupted concertedly. The maximal value of the rate constant (keff) describing the late phase of the reaction (strand separation) was 0. 5 s-1, which was 4-fold greater than kcat. Release of HF31 from E. HF31 in the presence of ATP (0.21 s-1) was the major contributor to kcat. At saturating ATP and competitor DNA concentrations, the enzyme unwound 44% of F21:HF31 that was initially bound to the enzyme (low processivity). These results are consistent with a passive mechanism for strand separation of F21:HF31 by HCV helicase.     

Black Creek Canal Virus infection in Sigmodon hispidus in southern Florida

Flexor pulleys in the hindpaw digits of twenty-eight adult mixed-breed dogs were reconstructed in order to investigate the influence, on the reconstruction, of the source of the autogenous tissue (intrasynovial compared with extrasynovial tendon) and the tension applied during the repair. The ipsilateral peroneus longus tendon was used to reconstruct the A2 pulley with an around-the-bone technique in twenty-one digits; the graft was sutured at a tension of 0.49, 0.98, and 1.96 newtons in seven digits each. The flexor digitorum profundus tendon of an adjacent digit was used to reconstruct the A2 pulley, at a tension of 0.98 newton, in seven additional digits. The contralateral digits were used as controls for all twenty-eight treated digits. The digits were tested in a custom apparatus designed to measure the frictional force generated between the reconstructed pulley and the tendon beneath it. The frictional force did not differ significantly (p > 0.5) among the three groups repaired with peroneus longus tendon; however, the average value was more than five times that produced in the contralateral, control digits. The average frictional forces created by the flexor digitorum profundus grafts were similar to those in the contralateral, control digits. Reconstruction with the flexor digitorum profundus at a tension of 0.98 newton produced significantly less frictional force (p < 0.05) than that produced by the peroneus longus graft at the same tension. This in vitro model of reconstruction of the A2 pulley demonstrated that tendon from an intrasynovial source (the flexor digitorum profundus) produced less frictional resistance to gliding of the tendon than did tendon from an extrasynovial source (the peroneus longus). This result is consistent with previously published findings that intrasynovial tendons may make better grafts than extrasynovial tendons for the reconstruction of gliding flexor tendons because of decreased friction and better healing qualities. Intrasynovial tendons may also make better grafts for the reconstruction of flexor pulleys.     

The 58-kilodalton inhibitor of the interferon-induced double-stranded RNA-activated protein kinase is a tetratricopeptide repeat protein with oncogenic properties

The interferon-induced RNA-dependent protein kinase (PKR) is considered to play an important role in the cellular defense against viral infection and, in addition, has been suggested to be a tumor suppressor gene because of its growth-suppressive properties. Activation of PKR by double-stranded RNAs leads to the phosphorylation of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) and a resultant block to protein synthesis initiation. To avoid the consequences of kinase activation, many viruses have developed strategies to down-regulate PKR. Recently, we reported on the purification and characterization of a cellular inhibitor of PKR (referred to as p58), which is activated during influenza virus infection. Subsequent cloning and sequencing has revealed that p58 is a member of the tetratricopeptide repeat (TPR) family of proteins. To further examine the physiological role of this PKR inhibitor, we stably transfected NIH 3T3 cells with a eukaryotic expression plasmid containing p58 cDNA under control of the cytomegalovirus early promoter. By taking advantage of a recently characterized p58 species-specific monoclonal antibody, we isolated cell lines that overexpressed p58. These cells exhibited a transformed phenotype, growing at faster rates and higher saturation densities and exhibiting anchorage-independent growth. Most importantly, inoculation of nude mice with p58-overexpressing cells gave rise to the production of tumors. Finally, murine PKR activity and endogenous levels of eIF-2 alpha phosphorylation were reduced in the p58-expressing cell lines compared with control cells. These data, taken together, suggest that p58 functions as an oncogene and that one mechanism by which the protein induces malignant transformation is through the down-regulation of PKR and subsequent deregulation of protein synthesis.     

Measurement of response to treatment in colorectal liver metastases

Assessment of tumour response to chemotherapy is important when assessing efficacy of treatment and comparing differing therapeutic regimens. Percentage hepatic replacement (PHR) is commonly used to assess response to treatment of colorectal hepatic metastases. PHR is dependent not only on tumour volume, but also on hepatic parenchymal volume. The effect of tumour growth on hepatic parenchymal volume is unclear but is of importance owing to its effect on PHR. We assessed tumour and hepatic parenchymal weights in an animal tumour model using dissection, and tumour and hepatic parenchymal volumes in patients with colorectal hepatic metastases using CT scanning, in order to establish how hepatic parenchyma varied with change in metastasis size. There was no significant correlation between tumour and liver parenchyma in either the animal model (r = -0.03, P > 0.05) or the patient study (r = 0.3, P < 0.05). This suggests that hepatic parenchymal volume was preserved in the presence of increasing tumour volume. In a further study of computerised tomographic (CT) scans before and after treatment in patients whose tumours either responded to chemotherapy or continued to grow, change in PHR (median proportion of PHR change = 0.40) significantly (P = 0.04) underestimated the change in tumour volume (median proportion of tumour volume change = 0.56), particularly at higher (> 400 ml) volumes. There was good correlation between change in tumour volume and WHO criteria in assigning patients to tumour growth, stable disease or tumour response categories. This study suggests that, in clinical trials comparing colorectal liver metastasis treatments, metastasis volume and not PHR should be used to assess extent of disease and the effect of treatment.