Human immunodeficiency virus type 1 central DNA flap: dynamic terminal product of plus-strand displacement dna synthesis catalyzed by reverse transcriptase assisted by nucleocapsid protein.

To terminate the reverse transcription of the human immunodeficiency virus type 1 (HIV-1) genome, a final step occurs within the center of the proviral DNA generating a 99-nucleotide DNA flap (6). This step, catalyzed by reverse transcriptase (RT), is defined as a discrete strand displacement (SD) synthesis between the first nucleotide after the central priming (cPPT) site and the final position of the central termination sequence (CTS) site. Using recombinant HIV-1 RT and a circular single-stranded DNA template harboring the cPPT-CTS sequence, we have developed an SD synthesis-directed in vitro termination assay. Elongation, strand displacement, and complete central flap behavior were analyzed using electrophoresis and electron microscopy approaches. Optimal conditions to obtain complete central flap, which ended at the CTS site, have been defined in using nucleocapsid protein (NCp), the main accessory protein of the reverse transcription complex. A full-length HIV-1 central DNA flap was then carried out in vitro. Its synthesis appears faster in the presence of the HIV-1 NCp or the T4-encoded SSB protein (gp32). Finally, a high frequency of strand transfer was shown during the SD synthesis along the cPPT-CTS site with RT alone. This reveals a local and efficient 3'-5' branch migration which emphasizes some important structural fluctuations within the flap. These fluctuations may be stabilized by the NCp chaperone activity. The biological implications of the RT-directed NCp-assisted flap synthesis are discussed within the context of reverse transcription complexes, assembly of the preintegration complexes, and nuclear import of the HIV-1 proviral DNA to the nucleus toward their chromatin targets.

Evidence of iodine storage within thyroid stroma after iodine treatment: imaging by secondary ion mass spectometry (SIMS) microscopy in goitrous tissue.

We measured the 127I distribution within tyroid tissue to find out where intrathyroid iodine was deposited during iodine treatment in eight Tunisian female patients (aged 33-58 yr) with endemic euthyroid goiter. Before surgery, five patients were treated during 6 months either by Lugol's solution (group 1: three patients) or by Lugol's and L-thyroxine (group 2: two patients). All patients remained euthyroid during the course of the treatment, which supplied 3.8 mg/day iodine. Three other patients did not receive Lugol's solution (control group). Secondary ion mass spectrometry microscopy was used to map 127-I quantitatively on thyroid sections. Specimens obtained at thyroid surgery were divided macroscopically into nodular and extranodular tissue and chemically fixed to preserve organified iodine. The iodine profile of patients in group 1 did not differ from that in group 2: large amounts of iodine were localized in thyroid follicles and stroma of both nodular and extranodular tissues. In the control group, iodine within stroma was found only in the extranodular tissue. Despite the limited number of patients studied, these data suggest that stromal iodine might represent a storage compartment in times of large iodine supply.

Signal standardization of the secondary ion mass spectrometry (SIMS) microscope for quantification of halogens and calcium in biological applications.

The secondary ion mass spectrometry (SIMS) microscope is able to map chemical elements in tissue sections. Although absolute quantification of an element remains difficult, a relative quantitative approach is possible for soft tissue by using carbon (12C) as an internal reference present at large homogeneous and constant concentration in specimen and embedding resin. In this study, this approach is used to standardize the signal of an SIMS microscope for the quantification of halogens (9F-, 35Cl- and 79Br-) and calcium (40Ca+). Standard preparation was determined based on homogeneity and stability criteria by molecular incorporation (halogens) or mixing (calcium) in methacrylate resin. Standard measurements were performed by depth analysis on areas of 8 microns (halogens) and 150 microns (calcium) in diameter for 10-30 min, under Cs+ (halogens) or Ox+ (calcium) bombardment. Results obtained from 100-120 measurements for each standard dilution show that the relationship between the signal intensity measured and the elemental concentration (micrograms/mg of wet tissue or mM) is linear in the range of biological concentrations. This quantitative approach was applied firstly to bromine of the 5-bromo-2'-deoxyuridine (BrdU) used as nuclear marker of rat hepatocytes in proliferation. The second model concerns depletion of calcium concentration in cortical compartment in Paramecium tetraurelia during exocytosis. Then signal standardization in SIMS microscopy allows us to correlate quantitative results with those obtained from other methods.

Assessing intratumor distribution and uptake with MBBG versus MIBG imaging and targeting xenografted PC12-pheochromocytoma cell line.

UNLABELLED: The heterogeneity of tumor uptake is likely to substantially limit the effectiveness of metaiodobenzylguanidine (MIBG) therapy. This study was done to establish whether metabromobenzylguanidine (MBBG) can target neuroendocrine tumors and to provide intratumor biodistribution and uptake information in comparison to MIBG. METHODS: MBBG and MIBG tumor uptake and kinetic studies were performed in experimental PC-12 pheochromocytoma grown in nude mice. Intratumor distribution studies were performed using autoradiography and secondary ion mass spectrometry (SIMS) microscopy, because the latter technique can detect and potentially quantify both drugs concomitantly within the same tumor specimen. RESULTS: MBBG uptake in PC12 tumors was early (2 hr) and intense (80% ID/g). Retention values were similar for both drugs 24 hr postinjection. At the cellular level, MBBG mostly accumulated in the cytosol. At the multicellular level, cells exhibited staining, but in many areas, SIMS images of both drugs were not spatially correlated. CONCLUSION: MBBG targeted experimental pheochromocytoma efficiently with high early uptake values. Bromine-76-MBBG is a promising means of imaging and quantifying tumor uptake with PET. Both drugs were localized in the cytosol, but the correlation between the two distributions, as assessed by the values of the standardized local concentrations, was weak although significant multicellularly.

Recent developments in medical applications of SIMS microscopy.

The purpose of this review is to present the recent developments in the medical applications of SIMS microscopy. This technique is one of the microanalytical mass spectrometry methods which allow in theory the detection of all the elements of the Mendeleiev table as well as the separation of stable and radioactive isotopes. It is based on a phenomenon whereby a biological sample surface is sputtered by bombardment with an energetic 'primary ion' beam. Part of the sputtered matter is ionized and the resulting 'secondary ions' are characteristic of the atomic composition of the analyzed area. These secondary positive or negative ions are collected and separated in a mass spectrometer at low or high mass resolution, which is dependent on both the element studied and its concentration. An analytic image which conserves the tissue distribution of the selected element is displayed on a fluorescent screen linked to an image processing system. Local elemental concentration can also be measured. Results are highly dependent on the techniques used for sample preparation which should preserve both the chemical and the structural integrity of the tissue. Further, the ionic images must be correlated with corresponding images of the same areas of the serial sections observed in a photonic microscope. With our SIMS microscope (lateral resolution approximately 0.5 microns, and mass resolution 300 to 12,000) we have demonstrated that this microscopic imaging technique is suitable for physiopathological studies. We revisited thyroid iodine metabolism by mapping chemical elements such as 32S and 127I, characteristic of hormonal physiology. Newly organified iodine (radioiodine) can be evaluated in relation to previously stored iodine (127I) in a given follicle, thus allowing an appraisal of glandular adaptation to aging and iodine overload. Another area in which SIMS can be used in medicine, is for the localization of drug markers in tumor tissue (e.g. fluorine-5-fluouracil, iodine in iododeoxyrubicin). This could facilitate the evaluation of the intratumor drug concentration at the onset of the treatment. Likewise, SIMS can be used to localize radiopharmaceuticals used in diagnosis (e.g. technetium) and therapy (131I of metaiodobenzylguanidine). This would permit a better evaluation of the radiation dose delivered to tissue. Further prospects are within reach with the imminent advent of higher lateral resolution (0.05 microns) SIMS microscopes.

Radioiodine uptake as a function of stored iodine and thyroglobulin in thyroid follicles: in vitro quantitative imaging approach with secondary ion mass spectrometry (SIMS) microscopy in human nontoxic goiter.

We studied by an imaging technique, secondary ion mass spectrometry (SIMS) microscopy, the ability of thyroid follicles to pick-up and organify radioiodine (125I) according to the amounts of iodine (127I) and sulfur previously stored in thyroglobulin (Tg). After incubation with radioiodine in miniorgan culture, the SIMS analysis of 14 fragments from 12 goitrous patients permitted the observation of 3 iodine distribution profiles. In group 1 125I and 127I were easily detected by imaging; 125I concentration in follicular lumen was 80-fold lower than that of 127I. In group 2 125I images were obtained after long-term exposure and image processing. 125I concentration was not measurable while that of 127I was about 1.7-fold higher than that observed in group 1. In group 3 it was not possible to detect 125I while only traces of 127I were detected. This last profile can coexist with profile 1 in the same specimen. Tg sulfur concentration was 2-fold lower in group 3 than in the other 2 groups in which they were almost the same and significantly correlated with those of 127I. These data provide new insight into Tg and 127I traffic in the development of nonfunctioning goiters.

SIMS microscopy imaging of the intratumor biodistribution of metaiodobenzylguanidine in the human SK-N-SH neuroblastoma cell line xenografted into nude mice.

Microdosimetric evaluations of targeted radiotherapy of neuroblastoma with metaiodobenzylguanidine (MIBG) require precise assessment of the intracellular and intratumor distribution of the drug. We report the use of secondary ion mass spectrometry (SIMS) microscopy, a technique capable of mapping any chemical element within a biological specimen, to determine 127I-MIBG biodistribution in human neuroblastoma SK-N-SH xenografted into nude mice. Highly specific images of 127I-MIBG biodistribution were mapped within the tumor after in vivo administration of the drug and sample processing with cryotechniques (high-speed freezing and cryo-embedding), which prevent MIBG diffusion from original sites of uptake. We showed that the biodistribution of the tracer was highly nonuniform within the tumor. At the cellular level, most of the drug accumulated in the cytosol and perinuclear areas. In contrast, chemical sample processing provided not only a considerable loss in sensitivity due to passive diffusion of the drug in the organic solvents, but also artefactual images mainly due to MIBG redistribution onto the cell nuclei. Based on our findings in this SK-N-SH experimental tumor model, we suggest that MIBG should be attached to long-range emitters, in the hope of irradiating the many tumorous areas that remain carrier-free.

Significance of secondary ion mass spectrometry microscopy for technetium-99m mapping in leukocytes.

Secondary ion mass spectrometry (SIMS) microscopy is the only method potentially capable of mapping all the elements in the periodic table including stable and radioactive isotopes. We used this method to study 99mTc distribution by detecting and localizing of 99Tc, a daughter product which has the same mass and the same chemical properties. It was combined with albumin macroaggregates or with Hexamethylpropylene-amine oxime (HMPAO) in leukocytes. The efficiency of 99Tc ionization under Cs+ bombardment was higher than with an O2+ beam. By using high mass resolution we succeeded in detecting and localizing 99Tc in cell sections by eliminating polyatomic ions that arise from this biological matrix. The 99Tc specific signal was obtained with a mass resolution of 2000 for labeled albumin macroaggregates, and 5000 for HMPAO-labeled leukocytes. In the latter, the labeling varied from one cell to another and 99Tc was present in both the nucleus and the cytoplasm. The results indicate that SIMS microscopy can provide new insights into 99mTc dosimetry.

SIMS microscopy in the biomedical field.

We attempted to indicate the requirements for biomedical applications of SIMS microscopy. Sample preparation methodology should preserve both the structural and the chemical integrity of the tissue. Furthermore, it is often necessary to correlate ionic and light microscope images. This implies a common methodological approach to sample preparation for both microscopes. The use of low or high mass resolution depends on the elements studied and their concentrations. To improve the acquisition and processing of images, digital imaging systems have to be designed and require both ionic and optical image superimposition. However, the images do not accurately reflect element concentration; a relative quantitative approach is possible by measuring secondary ion beam intensity. Using an internal reference element (carbon) and standard curves the results are expressed in micrograms/mg of tissue. Despite their limited lateral resolution (0.5 microns) the actual SIMS microscopes are very suitable for the resolution of biomedical problems posed by action modes and drug localization in human pathology. SIMS microscopy should provide a new tool for metabolic radiotherapy by facilitating dose evaluation. The advent of high lateral resolution SIMS imaging (less than 0.1 microns) should open up new fields in biomedical investigation.

Significance of SIMS microscopy for the radioiodine detection in animal and human thyroid tissue.

We defined the SIMS conditions for radioiodine detection in animal and man thyroid follicles, in tissue sections (3 microns) chemically fixed and resin embedded. Two radioisotopes were tested: 125I and 129I, of high (14 mCi 125I micrograms-1) and low specific activity (1.07 10(-6) mCi 129I micrograms-1). In animal study, Wistar rats fed a normal iodine diet (10 micrograms 127I day-1) were injected ip 24 h before sacrifice either with 125I (7 10(-3) micrograms) or with 129I at a dose identical to iodine diet (10 micrograms) or 3 times higher (30 micrograms). No SIMS signal of 125I was obtained in vivo due to its too low concentration, while radioiodine distribution was evidenced with both doses of 129I. Local concentration of previously stored 127I in follicular lumen was not modified, when compared to control (4.14 +/- 0.03 micrograms/mg, m +/- SE), by 125I or 129I at a dose of 10 micrograms, but was nearly doubled with 129I at a dose of 30 micrograms, proof of a pharmacological effect on thyroid iodine regulation. In human study 129I was excluded due to its long half-life (1.6 10(7) years), and 125I was tested only in vitro on two surgical specimens of normal perinodular thyroid tissue maintained in mini-organ culture for 48 h in presence of 100 microCi/ml of 125I. The 125I was detectable, its concentration was 1,000-fold higher than that of 127I (1.5 +/- 0.004 micrograms/mg). For both in vivo and in vitro studies, a positive correlation exists between newly organified radioiodine (125I or 129I) and previously stored iodine (127I).(ABSTRACT TRUNCATED AT 250 WORDS)

[Direct evaluation of thyroid I-127 in an iodine overload situation: in vivo study by X-ray fluorescence and in vitro by analytical ion microscopy]. / Evaluation directe de l'127I thyroïdien en situation de surcharge iodée: etude in vivo par fluorescence X et in vitro par microscopie ionique analytique.

This review describes the two methods which allow direct estimation of stable iodine (127I) within thyroid gland either in vivo by X-ray fluorescence or in vitro by secondary ion mass spectrometry (SIMS) microscopy on tissue section. Although the measurement of thyroid iodine content (TIC) by X-ray fluorescence has little relevance for routine explorations of thyroid function, this is a valuable method for understanding complex pathophysiological conditions such as the thyroid adaptation to iodine overload. On the other hand, SIMS microscopy which is able to characterize the functional activity of thyroid tissue by measuring 127I concentration within the thyroid follicles, can be used to determine the extent to which exogenous iodine affects the regulation of iodine within the thyroid follicles. Both methods were used to evaluate the quantitative changes in thyroid 127I induced by amiodarone iodine overload. TIC measurements shows that hyperthyroidism occurred only in patients who increased their iodine stores, while the patients who developed hypothyroidism had low iodine stores. The SIMS microscopy data obtained in mice demonstrated that the thyroid response to amiodarone is related to dietary iodine intake leading to an increase in local iodine concentration in iodine deficient mice and to a decrease in iodine supplemented mice. This response is specific and different from that induced by an iodide overload. These results could explain that hyperthyroidism with high thyroid iodine content occurred in areas with low thyroid iodine intake and hypothyroidism with low thyroid iodine content in areas with a supplemented iodine diet.

Acute effects of various doses of iodide on thyroid iodine autoregulation. A study with 129I by means of analytical ion microscopy.

Analytical ion microscopy (AIM) was used to determine alterations in the thyroid follicular lumen 127I stores of Wistar rats injected with different doses of 129I (low specific activity radionuclide). Animals fed a normal iodine diet (10 micrograms 127I/d) were divided into four groups: control group and three treated groups injected ip 24 h before sacrifice with 129I at doses of 10 micrograms (group 1), 30 micrograms (group 2), and 8500 micrograms (group 3). AIM was performed on thyroid semithin sections. The mean 129I concentration increased with the dose injected from group 1 (0.44 +/- 0.03 micrograms/mg, mean +/- SEM) to group 2 (2.05 +/- 0.14 micrograms/mg) and decreased in group 3 (0.57 +/- 0.08 microgram/mg). When compared to control group (4.14 +/- 0.17 micrograms/mg), the mean 127I concentration was not changed in group 1 (4.52 +/- 0.07 micrograms/mg), but altered in the other groups: It was significantly increased (7.14 +/- 0.41 micrograms/mg) in group 2 and slightly decreased (3.11 +/- 0.26 micrograms/mg) in group 3. These results underline the interest of AIM in the study of the effects of various doses of iodide on the thyroid autoregulation by iodide, a trace element actively trapped by this gland.

A monoclonal antibody to the double-stranded polyribonucleotide complex poly(A) X poly(U).

A monoclonal antibody to the double-stranded polyribonucleotide complex poly(A) . poly(U) was derived from the fusion of spleen cells from immunized DBA/2 mice and the P3 X X63-Ag8 plasma cytoma. Specificity studies using radioimmunoassays showed that the anti-poly(A) . poly(U) does not cross-react with single-stranded polyribonucleotides. RNA X DNA hybrids or DNAs. In addition to RNA duplexes associating adenine and uracil, it recognizes synthetic poly(I) . poly(C) and naturally occurring reovirus RNA. It is thus directed against a conformational epitope with an absolute requirement for two polyribose phosphate chains. However, the antibody does not cross-react with poly(G) . poly(C) and is therefore able to distinguish between RNA double helices.