Tumor targeting of radiometal labeled anti-CEA recombinant T84.66 diabody and t84.66 minibody: comparison to radioiodinated fragments

Recombinant antibody fragments offer potential advantages over intact monoclonal antibodies in the radioimmunoscintigraphy (RIS) of solid tumors. Due to their smaller molecular size, antibody fragments have shown rapid tumor targeting and blood clearance, a more uniform tumor distribution and a lower potential to elicit a human immune response. Previously, we have expressed two genetically engineered antibody fragments, the T84.66 diabody (scFv dimer) and the T84.66 minibody (scFv-CH3 dimer), specific to carcinoembryonic antigen (CEA). When radioiodinated, both antibody fragments exhibited rapid tumor targeting and rapid blood clearance in xenografted mice. To extend and optimize their future clinical RIS utility with radiometals, these antibody fragments were conjugated with the macrocycle 1,4,7,10-tetraazacyclododecane N,N',N' ',N' "-tetraacetic acid (DOTA) and labeled with 111In. Tumor targeting and biodistribution studies were carried out in athymic mice xenografted with a human colorectal tumor cell line, LS174T. The [111In]T84.66 diabody (55 kDa) exhibited very rapid tumor targeting with 12.5 +/- 0.4% injected dose per gram (% ID g(-1) +/- standard error) at 2 h and reached a maximum of 13.3 +/- 0.9% ID g(-1) at 6 h. However, kidney uptake was observed to reached a peak of 183.5 +/- 21.0% ID g(-1) at 6 h, a result similar to that reported by others for other low molecular weight fragments labeled with radiometals. Preadministration of an oral dose of D-lysine resulted in a 59% lowering of the renal accumulation at 6 h, but was accompanied by a 31% reduction of tumor uptake to 9.2 +/- 1.2% ID g(-1). The second recombinant antibody fragment, the [111In]T84.66 minibody (80 kDa), displayed rapid tumor targeting of 14.2 +/- 6.1% ID g(-1) at 2 h, and reached a maximum activity of 24.5 +/- 6.1% ID g(-1) by 12 h. Renal uptake achieved a plateau of 12-13% ID g(-1) which cleared to 7.2% ID g(-1) at 72 h. However, hepatic uptake was elevated and reached a maximum of 26.0 +/- 1.0% ID g(-1) at 12 h in these xenograft-bearing mice. Experiments in nontumor bearing mice showed a reduction of hepatic activity at 12 h to 16.6 +/- 1.5% ID g(-1), indicative of an intrinsic hepatic accumulation of the [111In]DOTA-T84.66 minibody or metabolites. While the anti-CEA [111In]DOTA-T84.66 diabody and T84.66 minibody retain the rapid tumor targeting properties of the radioiodinated form, the normal organ accumulation (kidneys and liver, respectively) of the [111In]DOTA forms appeared problematic for RIS and RIT applications. Development of alternative blocking strategies or new metabolizable chelates are under investigation to enhance the utility of the radiometal form of these and other promising recombinant antibody fragments.     

Renal metabolism of 3'-iodohippuryl N(epsilon)-maleoyl-L-lysine (HML)-conjugated Fab fragments

Renal localization of radiolabeled antibody fragments constitutes a problem in targeted imaging and radiotherapy. Recently, we reported use of a novel radioiodination reagent, 3'-[131I]iodohippuryl N(epsilon)-maleoyl-L-lysine (HML), that liberates m-iodohippuric acid before antibody fragments are incorporated into renal cells. In mice, HML-conjugated Fab demonstrated low renal radioactivity levels from early postinjection times. In this study, renal metabolism of HML-conjugated Fab fragments prepared by different thiolation chemistries and by direct radioiodination were investigated to determine the mechanisms responsible for the low renal radioactivity levels. Fab fragments were thiolated by 2-iminothiolane modification or by reduction of disulfide bonds in the Fab fragments, followed by conjugation with radioiodinated HML to prepare [131I]HML-IT-Fab and [125I]HML-Fab, respectively. In biodistribution studies in mice, both [131I]HML-IT-Fab and [125I]HML-Fab demonstrated significantly lower renal radioactivity levels than those of [125I]Fab. In subcellular distribution studies, [125I]Fab showed migration of radioactivity from the membrane to the lysosomal fraction of the renal cells from 10 to 30 min postinjection. On the other hand, the majority of the radioactivity was detected only in the membrane fraction at the same time points after injection of both [131I]HML-IT-Fab and [125I]HML-Fab. In metabolic studies, while [125I]Fab remained intact at 10 min postinjection, both HML-conjugated Fab fragments generated m-iodohippuric acid as a radiometabolite at the same postinjection time. [131I]HML-IT-Fab registered two radiometabolites (intact [131I]HML-IT-Fab and m-iodohippuric acid), whereas additional radiometabolites were observed with [125I]HML-Fab. This suggested that metabolism of both HML-conjugated Fab fragments would occur in the membrane fractions of the renal cells. The findings of this study reinforced our previous hypothesis that radiochemical design of antibody fragments that liberate radiometabolites that are excreted into the urine by the action of brush border enzymes would constitute a useful strategy to reduce renal radioactivity levels from early postinjection times.     

Improved biodistribution and radioimmunoimaging with poly(ethylene glycol)-DOTA-conjugated anti-CEA diabody

Diabodies are single chain antibody fragments (scFvs) that spontaneously form bivalent dimers of molecular size 50-55000. Radiolabeled diabodies are almost ideal tumor targeting agents due to their high avidity (bivalent) binding to tumor antigens and small size (50-55000) that leads to improved tumor-to-blood ratio compared to intact antibodies (150000). However, due to their high retention and metabolism in the kidney, radioiodine is the current radiolabel of choice for diabodies since radioiodine is rapidly excreted from the kidney once metabolized. We have previously shown that 111In-DOTA-diabody gives higher tumor uptake in nude mouse xenografts than 125I-diabody, but has extremely high kidney retention since its 111In-labeled metabolites are retained by and only slowly excreted from the kidney. When a diabody is conjugated to a bifunctional PEG-3400 derivative followed by reaction with cysteinyl-DOTA, the resulting product has an apparent molecular size of 75000 and a Stokes radius of 35 angstroms on size exclusion chromatography, compared to a Stokes radius of 25 angstroms for intact diabody. When radiolabeled, the conjugate gives high yields of 111In-labeled product, retains high immunoreactivity, and gives improved biodistributions (30-40%ID/g, 12-48 h) compared to 111In-DOTA-diabody (12-13%ID/g, 6-12 h). We show that the improved biodistribution is due to an increase in Stokes radius caused by the linear PEG-3400 since conjugation of diabody with multiple (PEG)12 linkers followed by reaction with cysteinyl-DOTA does not reduce kidney accumulation. We also show that 111In-cysteinyl-DOTA-PEG3400-diabody gives excellent tumor images in the nude mouse xenograft model and that 125I-PEG3400-diabody gives equivalent images to 125I-minibody (molecular size, 80000), but improved tumor-to-liver ratios, suggesting that this imaging agent can be used to image liver metastases.     

Studies on the metabolic fate of 111In-labeled antibodies

Indium-111-labeled antibodies, though providing superior photon flux to iodine-labeled antibodies, can exhibit high levels of accumulation in some non-target organs. In an effort to understand the nature of this non-target uptake we have evaluated the molecular weight of ¹¹¹In species retained in several tissues by radio-FPLC (sizing chromatography) following injection of [¹¹¹In]DTPA 5G6.4, a murine monoclonal antibody, into normal mice. Blood, liver and kidneys were removed, and liver and kidneys were homogenized at several time points after antibody injection. The proportion of ¹¹¹In-containing species was found to vary with the tissue and with time. Analysis of blood showed only radiolabeled antibody. In the liver, several ¹¹¹In species were identified with molecular weights compatible with intact antibody, [¹¹¹In]transferrin, and low molecular weight complexes, with an increase in the proportion of [¹¹¹In]transferrin and low molecular weight species occurring over time. While the same molecular weight species were also identified in the kidneys, the kidneys contained the largest percentage of low molecular weight species which increased over time. When ¹²⁵I-labeled 5G6.4 was injected and the tissues similarly analyzed, only radioactive material with the molecular weight of intact antibody was detected. Comparison of two methods of purification of [¹¹¹In]labeled antibody after labeling revealed a significant difference in the organ uptake of radiolabeled products for ¹¹¹In. Although dialysis was sufficient for the removal of labile ¹¹¹In, as determined by TLC, subsequent sizing chromatography on Bio-Gel P-60 dramatically dropped the hepatic and renal uptake of ¹¹¹In relative to blood and diminished the proportion of the low molecular weight species present on sizing FPLC of extracts from tissues. These data indicate that low and intermediate molecular weight ¹¹¹In compounds are accreted in the liver and kidneys following the i.p. injection of ¹¹¹In-labeled monoclonal antibodies and that their uptake can be diminished by more stringent radioantibody purification. This knowledge may be valuable in developing methods for reducing non-target ¹¹¹In uptake.     

Chemical modification to reduce renal uptake of disulfide-bonded variable region fragment of anti-Tac monoclonal antibody labeled with 99mTc.

The anti-Tac disulfide-bonded variable region fragment (dsFv) is a genetically engineered, 25 kDa, murine monoclonal antibody fragment that recognizes the alpha subunit of the interleukin-2 receptor (IL-2Ralpha). The dsFv radiolabeled with the tetrafluorophenyl ester (TFP) of [99mTc]mercaptoacetyltriglycine ([99mTc]MAG3-TFP) showed rapid tumor uptake and fast blood clearance in mice, resulting in high tumor-to-nontumor background ratios. However, its high renal uptake was a problem. In this study, we tested the effect of lowering the isoelectric point (pI) of dsFv to <9.3 on renal and tumor uptake. To lower the pI, dsFv was acylated simultaneously with both [99mTc]MAG3-TFP and TFP-glycolate. The acylation of dsFv decreased its pI and its immunoreactivity inversely proportional to the molar ratio of TFP-glycolate to dsFv, whereas the conjugation of [99mTc]MAG3-TFP alone did not. When biodistribution studies were performed in nude mice, the effect of the lowered pI was reflected primarily in decreased kidney uptake and whole-body retention, with its highest effect seen at the earliest time point (15 min) after injection. In tumor-bearing nude mice, glycolated [99mTc]MAG3-dsFv with a pI range of 4.9 to 6.5 accumulated selectively into IL-2 receptor-positive SP2/Tac tumor similar to that of the control [125I]dsFv labeled by the Iodo-Gen method, whereas its renal uptake was 25% of [125I]dsFv at 15 min. At 90 min, the ratios of tumor to receptor-negative SP2/0 tumor, liver, kidney, stomach, and blood had peaked at 10.9, 8.5, 0.3, 5.0, and 6.2, respectively, for the glycolated [99mTc]MAG3-dsFv. The corresponding ratios for [125I]dsFv were 3.7, 5.0, 0.1, 1.5, and 2.1, respectively.     

Synthesis and processing of lysosomal enzymes of mouse kidney after treatment with [3H]fucose

[3H]Fucose, intravenously injected into androgen-treated mice, was incorporated at high rates into the immunopurified kidney lysosomal enzymes beta-glucuronidase and beta-galactosidase. Initially, label was incorporated into high molecular weight proenzyme forms. Processing of fucose-labeled proenzyme forms to lower molecular weight mature forms was very rapid, being detectable at 30 min, and complete by 90 min, compared with the several hours required for processing of lysosomal enzymes labeled with amino acids. This result is consistent with addition of fucose residues within the Golgi apparatus just before transfer of lysosomal proenzyme forms to the lysosome where maturation is thought to occur. The combination of the high rates of incorporation of [3H]fucose and the known metabolic stability of this precursor sugar suggests that the mouse kidney system is advantageous for studies of the synthesis, processing, and degradation of fucose-containing complex oligosaccharides of lysosomal enzymes and, by extension, of other kidney glycoproteins.     

Reduction of kidney uptake in radiometal labeled peptide linkers conjugated to recombinant antibody fragments. Site-specific conjugation of DOTA-peptides to a Cys-diabody

Arano and co-workers (Arano et al. (1999) Cancer Res. 59, 128-134) have synthesized peptides with an N-terminal radioiodinated hippuric acid and a C-terminal lysine linked to antibody fragments via the epsilon-amino group of lysine that show reduced kidney uptake compared to antibody fragments directly radioiodinated. This approach takes advantage of the lysine specific carboxypeptidase activity of the kidney brush border enzymes that cleave off the radiolabeled peptide linker from the antibody fragment prior to uptake by proximal tubule cells. On the basis of their approach, we have synthesized a tetrapeptide with an N-terminal DOTA (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid) and a C-terminal (N(epsilon)-maleoyl)lysine that was site-specifically conjugated to an anti-CEA diabody (Yazaki et al. (2001) Bioconjugate Chem. 12, 220-228) that was engineered to contain a C-terminal cysteine (Cys-diabody). Biodistributions of the In-111-radiolabeled conjugate in nude mice show significantly reduced kidney uptake (a maximum of 82%ID/g at 6 h) compared to In-111 radiolabeled DOTA-diabody (184%ID/g at 6 h) in which DOTA was conjugated to endogenous lysine residues using DOTA-active ester chemistry. To further reduce kidney uptake, a homologous compound with a C-terminal (N(epsilon)-amino-1,6-hexane-bis-vinyl sulfone)lysine was synthesized and site-specifically conjugated to the Cys-diabody. Biodistributions of this In-111-labeled conjugate reduced kidney uptake to 54%ID/g at 6 h. To explore the effect of the relative positions of the chelate vs the cys-diabody on kidney uptake, we also synthesized a tetrapeptide with an N-terminal bromoacetate for conjugation to Cys-diabody and a C-terminal (N(epsilon)-amidino-propyl-3-thio-vinylsulfonyl-DO3A)lysine. This peptide essentially reverses the positions of the chelate and Cys-diabody attachment points on the peptide, while retaining the linker length on the epsilon-amino group of the lysine. In this case, biodistributions of the In-111-radiolabeled conjugate in nude mice showed high kidney uptake (189%ID/g at 6 h), comparable to that obtained with the In-111-radiolabeled active ester conjugated DOTA-diabody (184%ID/g at 6 h). We conclude that the peptide linker strategy of Arano and co-workers to reduce kidney uptake can be successfully applied to chelate/radiometal complexes and requires that the chelate/radiometal be located at the N-terminus of the peptide and the antibody fragment attachment site on the epsilon-amino group of the lysine. Furthermore, we demonstrated a role for the attachment chemistry to the epsilon-amino group of the lysine on the magnitude of kidney uptake.     

Distribution and metabolism of exogenous somatostatin in the rat

The mechanisms of clearance and degradation of injected [3H]somatostatin have been studied in the rat using octadecasilyl-silica extraction and HPLC separation methods.. Three apparent consecutive plasma half-lives of 1, 3 and 20 min were estimated following administration of a pharmacological dose. The initial rapid clearance was due to uptake by various tissue beds, mainly the large peripheral tissue masses muscle, skin and intestine which together accounted for 70% injected radioactivity at 1 min. By contrast the amounts taken up by liver and kidney were relatively small (less than 10%) despite the accumulation of higher concentrations. Massive degradation occurred following uptake and small fragments and amino acids were released into the circulation almost immediately. Inactivation by blood itself was negligible. A slow phase of decline observed at later times suggested a return of intact peptide from extravascular storage sites to sustain plasma concentrations.     

Antibody fragments labeled with fluorine-18 and gallium-68: In vivo comparison with indium-111 and iodine-125-labeled fragments

Although monoclonal antibodies have been radiolabeled with many different radionuclides, the application of positron emission tomography (PET) to the imaging of radiolabeled antibodies has been limited to the investigation of a small number of long-lived radionuclides. In this study, we labeled F(ab′)₂ fragments of a mouse monoclonal antibody (BB5-G1) specific for a human parathyroid surface antigen with the positron emitting radionuclides, gallium-68 and fluorine-18. The biodistribution of the fragments was evaluated in a nude mice model and the results were compared to those obtained with fragments labeled with iodine-125 and indium-111 using conventional labeling techniques. All labeled fragments bound to human parathyroid tissue implanted in nude mice, with parathyroid-to-muscle ratios reaching as high as 10:1, 4 h after administration. A major difference was observed in the uptake and clearance of the various labeled fragments through the kidney. The halogen activity cleared, but the metal radioactivity was retained in the kidney. The results indicate that the fluorine-18 or gallium-68 labeled fragment may be useful for parathyroid imaging with positron emission tomography.     

Comparison of the biodistribution of 75Se- and 131I-labelled monoclonal antibodies in nude mice

A monoclonal antibody, C-215, against colon cancer, was internally labelled with [⁷⁵Se]methionine. The biodistribution was studied in tumour-bearing nude mice and compared with the biodistribution of [¹³¹I]C-215. The tissue uptake was divided into three parts: antibody bound to the antigen, antibody in the extracellular space and uptake of the released radionuclide. [⁷⁵Se]C-215 showed a greater amount of antigen-bound antibody in the tumour, but also a greater unspecific uptake both in tumour and normal tissue.     

Use of antibody as carrier of oligomers of peptidomimetic alphavbeta3 antagonist to target tumor-induced neovasculature

Sulfhydryl selective reactions were explored to conjugate oligomers of a peptidomimetic integrin alphavbeta3 antagonist, 4-[2-(3,4,5,6-tetrahydropyrimidine-2-ylamino)ethyloxy]benzoyl-2-(S)-aminoethylsulfonylamino-beta-alanine (IA) to monoclonal antibody (MoAb) to increase integrin alphavbeta3 receptor-binding avidity. To generate sulfhydryl groups, N-succinimidyl-S-acetylthioacetate (SATA) was conjugated to both MoAb and IA. Sulfhydryl groups were then generated upon the deacetylation of the protecting acetyl group from the S-acetylthioacetato (ATA) moiety of MoAb-(ATA)n or IA-ATA with 0.02 M hydroxylamine in the presence of 1 mM EDTA at pH 7.2. The major focus was on optimizing the reaction concentrations, molar ratios, and reaction pH to conjugate high levels of IA-(A-SH) to MoAb-(A-SH)n without causing the inter- and intramolecular cross-linking of MoAb. Stepwise reactions of MoAb-(A-SH)n (15 microM MoAb) with a homobifunctional cross-linker, 1,8-bis(maleimido)diethylene glycol (BM[PEO]2) at a >50x molar excess to the -SH, followed by the reaction of the purified product MoAb-(A-S-succinimidomaleimido-[PEO]2)n with IA-(A-SH) at pH 7.2 afforded monomeric MoAb-(A-S-succinimido-[PEO]2-succinimido-S-A-IA)n with <10% high molecular weight oligomeric MoAb. Monomeric MoAb-(A-S-S-[PEO]2-S-S-A-IA)10 (MoAb-IA10) radiolabeled with 111In using 2-(p-isothiocyanatobenzyl)cyclohexyl-DTPA and with 125I using the Iodogen method showed >70% bindability to 0.4 microM alphavbeta3. When injected iv to nude mice with the receptor-positive M21 tumor, MoAb-IA10 radiolabeled with both 111In and 125I accumulated rapidly and was retained in the tumor for a 44 h period while the radioactivity cleared rapidly from the blood, thereby resulting in increasing tumor-to-blood ratios over time. The tumor uptake was similar between the 125I label and the 111In label for a 44 h period. In contrast, the blood radioactivity was lower, but liver and other organ uptakes were much higher for the 111In label than for the 125I. The 111In label produced higher tumor-to-blood ratios but much lower tumor-to-organ ratios than the 125I. The rapid blood clearance, a short peak tumor uptake time, and a low peak tumor uptake value with prolonged tumor retention of this macromolecule appear to support a hypothesis that MoAb-IA10 primarily binds to alphavbeta3 receptors on angiogenic vessels, but not on the tumor. This hypothesis was substantiated by the fluorescence microscopic analysis of FITC-MoAb-IA10, which showed that FITC-MoAb-IA10 outlined neovasculatures but not tumor cells at 4 and 21 h ex vivo. Additional proof was observed when blood vessels outlined with rhodamine-lectin, which specifically binds to blood vessels, were superimposable on neovasculatures outlined with FITC-MoAb-IA10.     

The metabolism of dipotassium 2-hydroxy-5-nitrophenyl [S]sulphate, a substrate for lysosomal arylsulphatases A and B

The metabolic fate of dipotassium 2-hydroxy-5-nitrophenyl [³⁵S]sulphate ([³⁵S]NCS), a chromogenic substrate for lysosomal arylsulphatases A and B, has been studied in rats. Intraperitoneal injection of [³⁵S]NCS into free-ranging animals is followed by excretion of the bulk of the radioactivity in the urine within 24hr., less than 13% being eliminated as inorganic [³⁵S]sulphate. Most of the urinary radioactivity can be accounted for as [³⁵S]NCS, but small amounts of a labelled metabolite are also present. Experiments in which [³⁵S]NCS was injected intravenously into anaesthetized rats with bile-duct and bladder cannulae confirm that the ester is rapidly excreted in the urine. However, small amounts of radioactivity appear in bile, mainly in the form of the metabolite detected in urine. When [³⁵S]NCS is perfused through the isolated rat liver, about 35% of the dose is hydrolysed within 3hr. Similar results are obtained if [³⁵S]NCS is injected into anaesthetized rats in which kidney function has been eliminated by ligature of the renal pedicles. The labelled metabolite has been isolated from bile obtained by perfusing several rat livers with blood containing a total of 100mg. of [³⁵S]NCS. It has been identified as 2-β-glucuronosido-5-nitrophenyl [³⁵S]sulphate. The implications of the various findings are discussed. The Appendix describes the preparation of [³⁵S]NCS.     

Metabolism of high-density lipoproteins in cultured rat luteal cells

The uptake of cholesterol from high-density lipoproteins (HDL) labeled with 125I and [3H]cholesterol was examined in cultured rat luteal cells. Luteal cells were incubated with labeled HDL, following which the metabolic fate of the apolipoproteins and cholesterol moieties of the receptor-bound HDL were examined. About 50% of the originally bound HDL apolipoproteins were released into the medium in 24 h by a temperature-dependent process while only 5% of the HDL cholesterol was released unmetabolized. Inclusion of unlabeled HDL in the chase incubation resulted in increased release of apolipoprotein-derived radioactive products without significant change in the release of unmetabolized cholesterol. 60% of the apolipoprotein-derived radioactivity could be precipitated with trichloroacetic acid; the remaining trichloroacetic acid-soluble radioactive fraction was identified as [125I]iodotyrosine. Gel filtration chromatography of the chase-released material showed that the trichloroacetic acid-precipitable products, which contained no detectable amounts of cholesterol, eluted over a range of molecular sizes (9-80 kDa). No intact HDL was retroendocytosed. About 80% of trichloroacetic acid-precipitable products could be immunoadsorbed on anti-apolipoprotein A-I antibody immobilized on CNBr-activated Sepharose, suggesting the presence of fragments containing apolipoprotein A-I. This material was also capable of reassociating with native HDL. Lysosomal inhibitors were partially effective in inhibiting the amount of trichloroacetic acid-soluble products formed. The lysosomal degradation appeared to have no role in the uptake of HDL-derived cholesterol. These studies demonstrate preferential and total uptake of HDL cholesterol by luteal cells, with concomitant degradation of the lipoprotein.     

Renal metabolism and urinary excretion of platelet-activating factor in the rat

The origin of platelet-activating factor (PAF) in the urine remains ill defined. The present study documents that [3H]PAF (3.5 mu Ci) injected into the renal artery of isolated control rat kidney preparations perfused at constant pressure with a cell-free medium containing 1% bovine serum albumin (BSA) was excreted in negligible amounts (0.034%) in the urine, whereas 6% was retained by the kidney. When kidneys were perfused with a BSA-free medium, 0.029 and 71% of the total radioactivity added to the perfusate was recovered in the urine and in the renal tissue, respectively. [3H]PAF urine excretion in proteinuric kidneys from adriamycin-treated rats was still negligible (0.015%). Analysis of the renal tissue-retained radioactivity in control and proteinuric kidneys perfused with 1% BSA indicated metabolism into long chain acyl-sn-glycero-3-phosphorylcholine species, lyso-PAF, glycerols, and intact PAF. Thin layer chromatography analysis of [3H]glycerol fraction in these renal extracts showed two major components comigrating with 1-O-alkylglycerol and 1-O-alkyl-2-fatty acylglycerol. Isolated proximal tubules, but not glomeruli from nephrotic rats exposed to increasing concentrations of BSA (0-4%), had a higher PAF uptake than control tubules for BSA concentrations ranging from 0 to 0.1%. Our findings in the isolated perfused kidneys indicate that, in normal conditions, circulating PAF is excreted in the urine in negligible amounts and that the altered glomerular permeability to proteins does not affect this excretion rate. Moreover, analysis of renal tissue radioactivity documented that the renal metabolism of PAF is comparable in control and nephrotic kidneys.     

In vitro and in vivo characterization of three 68Ga- and 111 In-labeled peptides for cholecystokinin receptor imaging

Cholecystokinin (CCK) receptors are overexpressed in several human tumor types, such as medullary thyroid carcinomas and small cell lung cancers. Several ligands for the CCK2 receptor (CCK2R) have been developed for radionuclide targeting of these tumors. In this study, we evaluated whether radiolabeled DOTA-sCCK8 and its stabilized derivative, DOTA-sCCK8[Phe(2)(p-CH2SO3H), Nle(3,6)], are suitable for imaging of CCK2R-positive tumors, using DOTA-MG0 as a reference. In vivo targeting of CCK2R-positive tumors with DOTA-sCCK8, DOTA-sCCK8[Phe(2)(p-CH2SO3H), Nle(3,6)], and DOTA-MG0, labeled with (111)In or (68)Ga, was evaluated in BALB/c nude mice with a subcutaneous A431-CCK2R tumor. Biodistribution studies and single-photon emission computed tomography (SPECT) and positron emission tomography (PET) were performed at 1 hour postinjection. All peptides specifically accreted in the CCK2R-expressing tumors. Both (111)In-DOTA-sCCK8 and (111)In-DOTA-sCCK8[Phe(2)(p-CH2SO3H), Nle(3,6)] showed good tumor retention (4.65% ID/g and 5.44% ID/g, respectively, at 4 hours postinjection). On PET/computed tomographic (CT) and SPECT/CT scans, subcutaneous A431-CCK2R tumors were clearly visualized with low uptake of sCCK8 peptides in the intestines. Whereas radiolabeled DOTA-MG0 showed high kidney uptake (70% ID/g), the sCCK8 peptides showed low uptake in the kidneys. Sulfated CCK8 analogues combined high tumor uptake with low retention in the kidney and are therefore promising tracers for imaging of CCK2R-positive tumors.     

Natural killer cell activity in the rat. V. The circulation patterns and tissue localization of peripheral blood large granular lymphocytes (LGL)

Large granular lymphocytes (LGL) and T cells were separated from blood by centrifugation on discontinuous gradients of Percoll, were labeled with [3H]uridine or [111In]oxine, and were injected i.v. into syngeneic euthymic or athymic nude rats. The tissue distribution of these labeled cells was monitored for up to 24 hr after transfer by scintillation counting of tissue homogenates and autoradiography of tissue sections. In normal euthymic rats, the main sites of LGL localization were the alveolar walls of the lungs and spleen red pulp; however, they were not detectable in the major traffic areas of T lymphocyte recirculation, the spleen white pulp, and lymph nodes. Furthermore, the density of labeled LGL was very low in the small intestine, thymus, kidney, and liver, although on a per-organ basis, about 10% of the injected radioactivity was found in the liver by 24 hr post-injection. When 111In-labeled LGL were injected i.v. into rats with an indwelling thoracic duct cannula, they completely failed to enter the thoracic duct lymphocyte (TDL) population over an observation period of 6 days. This finding was markedly different from the results obtained with T cells and was consistent with the lack of natural killer and antibody-dependent cellular cytotoxicity activity observed among TDL, even in rats pretreated with the biological response modifier, poly I:C. LGL in athymic nude rats also failed to recirculate between blood and lymph. However, in contrast to normal euthymic animals, a significant increase in the localization of radiolabeled LGL to lymph nodes was observed in nude rats between 30 min and 24 hr. Taken as a whole, these findings define the areas within the lungs and spleen in which blood LGL normally localize, and clearly demonstrate that LGL do not normally recirculate between blood and lymph.     

Linker effects on biological properties of 111In-labeled DTPA conjugates of a cyclic RGDfK dimer

In this report, we present in vitro and in vivo evaluation of three 111 In-labeled DTPA conjugates of a cyclic RGDfK dimer: DTPA-Bn-SU016 (SU016 = E[c(RGDfK)] 2; DTPA-Bn = 2-( p-isothioureidobenzyl)diethylenetriaminepentaacetic acid), DTPA-Bn-E-SU016 ( E = glutamic acid) and DTPA-Bn-Cys-SU016 (Cys = cysteic acid). The integrin alpha vbeta 3 binding affinities of SU016, DTPA-Bn-SU016, DTPA-Bn-E-SU016, and DTPA-Bn-Cys-SU016 were determined to be 5.0 +/- 0.7 nM, 7.9 +/- 0.6 nM, 5.8 +/- 0.6 nM, and 6.9 +/- 0.9 nM, respectively, against 125 I-c(RGDyK) in binding to integrin alpha vbeta3, suggesting that E or Cys residue has little effect on the integrin alpha vbeta3 affinity of E[c(RGDfK)] 2. It was also found that the 111 In-labeling efficiency of DTPA-Bn-SU016 and DTPA-Bn-E-SU016 is 3-5 times better than that of DOTA analogues due to fast chelation kinetics and high-yield 111 In-labeling under mild conditions (e.g., room temperature). Biodistribution studies were performed using BALB/c nude mice bearing U87MG human glioma xenografts. 111 In-DTPA-Bn-SU016, 111 In-DTPA-Bn-E-SU016, and 111 In-DTPA-Bn-Cys-SU016 all displayed rapid blood clearance. Their tumor uptake was comparable between 0.5 and 4 h postinjection (p.i.) within experimental error. 111 In-DTPA-Bn-E-SU016 had a significantly lower ( p < 0.01) kidney uptake than 111 In-DTPA-Bn-SU016 and 111 In-DTPA-Bn-Cys-SU016. The liver uptake of 111 In-DTPA-Bn-SU016 was 1.69 +/- 0.18% ID/g at 24 h p.i., while the liver uptake values of 111 In-DTPA-Bn-E-SU016 and 111 In-DTPA-Bn-Cys-SU016 were 0.55 +/- 0.11% ID/g and 0.79 +/- 0.15% ID/g at 24 h p.i., respectively. Among the three 111 In radiotracers evaluated in this study, 111 In-DTPA-Bn-E-SU016 has the lowest liver and kidney uptake and the best tumor/liver and tumor/kidney ratios. Results from metabolism studies indicated that there is little metabolism (<10%) for three 111 In radiotracers at 1 h p.i. Imaging data showed that tumors can be clearly visualized at 4 h p.i. with good contrast in the tumor-bearing mice administered with 111 In-DTPA-Bn-E-SU016. It is concluded that using a glutamic acid linker can significantly improve excretion kinetics of the 111 In-labeled E[c(RGDfK)] 2 from liver and kidneys.     

Carrier-mediated transport of monoiodotyrosine out of thyroid cell lysosomes

Monoiodotyrosine (MIT) crosses the lysosomal membrane of rat FRTL-5 thyroid cells by a carrier-mediated process. In egress studies, MIT lost from inside lysosomes was quantitatively recovered outside lysosomes as MIT, indicating that the compound was transported intact across the lysosomal membrane. In uptake studies, [125I]MIT entry required intact lysosomes and exhibited saturation kinetics. The apparent Km for MIT was approximately 1.5 microM and the Vmax was approximately 0.24 pmol/unit hexosaminidase/min. Countertransport of MIT was demonstrated, with an initial velocity of [125I]MIT uptake which reached a maximum at high intralysosomal MIT loading. Nonradioactive MIT and diiodotyrosine competed to approximately equivalent extents with [125I]MIT for uptake in countertransport experiments. The existence of a lysosomal MIT carrier in thyroid cells may explain how this product of thyroglobulin catabolism is transported to the cytosol for iodine salvage and reutilization.     

NODAGATOC,a new chelator-coupled somatostatin analogue labeled with [67/68Ga] and [111In] for SPECT,PET, and targeted therapeutic applications of somatostatin receptor (hsst2) expressing tumors

A monoreactive NOTA (1,4,7-triazacyclononane-1,4,7-triacetic acid) derived prochelator (1-(1-carboxy-3-carbo-tert-butoxypropyl)-4,7-(carbo-tert-butoxymethyl)-1,4,7-triazacyclononane (NODAGA(tBu)(3))) was synthesized in five steps with an overall yield of 21%. It is useful for the coupling to the N-terminus of peptides on solid phase and in solution; it was coupled to [Tyr3]-octreotide (TOC) on solid phase, and the resulting peptide, NODAGA-Tyr3-octreotide (NODAGATOC), was labeled with the radiometals 111In and 67Ga in high yields and good specific activities. [67Ga]- and [111In]-NODAGA-Tyr3-octreotide appear to be useful to visualize primary tumors and metastases which express somatostatin receptors subtype 2 (sstr2), such as neuroendocrine tumors, because of their high affinity to this receptor subtype with IC(50) = 3.5 +/- 1.6 nM and 1.7 +/- 0.2 nM, respectively. NODAGATOC could be used as a SPECT and PET tracer, when labeled with 111In, 67Ga, or 68Ga, and even for therapeutic applications. Surprisingly, [111In]-NODAGATOC shows 2 times higher binding affinity to sstr2, but also a factor of 4 higher affinity to sstr5 compared to [67Ga]-NODAGATOC. [67Ga]-NODAGATOC is very stable in serum and rat liver homogenate. There is no difference in the rate of internalization into AR4-2J rat pancreatic tumor cells; both radioligands are highly internalized, at 4 h a 3 times higher uptake compared to [111In]-DOTA-Tyr3-octreotide ([111In]-DOTATOC) was found. The biodistribution of [67Ga]-NODAGATOC in AR4-2J tumor bearing nude mice is very favorable at short times after injection; there is fast excretion from all nontarget organs except the kidneys and high uptake in sst receptor rich organs and in the AR4-2J tumor. Again it is superior to [111In]-DOTATOC in this respect. The results indicate an improved biological behavior which is likely due to the fact that an additional spacer group separates the chelate from the pharmacophoric part of the somatostatin analogue.     

Specific localization of In-111-labeled monoclonal antibody versus 67-Ga-labeled immunoglobulin in mice bearing human breast carcinoma xenografts

Summary A murine monoclonal antibody reacting with more than 95% of all breast cancers was radiolabeled with In-111 and injected IP into nude mice bearing human breast carcinoma xenografts, together with Ga-67-labeled normal mouse immunoglobulin. Images were produced with a gamma camera in dual isotope mode. Tumors could be localized clearly with In-111-labeled specific monoclonal antibody, but improved visualization was obtained after computer-assisted subtraction of the image with Ga-67-labeled nonspecific immunoglobulin. The tumor-to-tissue contrast was improved from 2.3 to 5.9 after subtraction. Imaging with In-111-radiolabeled monoclonal antibody was superior to imaging with iodinated antibody. For the first time it was shown that images of two chemically related isotopes, Ga-67 and In-111, coupled to nonspecific and specific antibody, respectively, and simultaneously injected, can be subtracted to show the preferential uptake of the specific antibody in the tumor. As these isotopes are routinely used in clinical practice this technique may prove to be more practical for immunodetection of tumors in patients than existing imaging techniques.