Affibody molecules are a class of small (ca. 7 kDa) robust scaffold proteins suitable for radionuclide molecular imaging of therapeutic targets in vivo. A hexahistidine tag at the N-terminus streamlines development of new imaging probes by enabling facile purification using immobilized metal ion affinity chromatography (IMAC), as well as convenient [⁹⁹(m)Tc(CO)₃](+)-labeling. However, previous studies in mice have demonstrated that Affibody molecules labeled by this method yield higher liver accumulation of radioactivity, compared to the same tracer lacking the hexahistidine tag and labeled by an alternative method. Two variants of the HER2-binding Affibody molecule Z(HER)₂(:)₃₄₂ were made in an attempt to create a tagged tracer that could be purified by immobilized metal affinity chromatography, yet would not result in anomalous hepatic radioactivity accumulation following labeling with [⁹⁹(m)Tc(CO)₃](+). In one construct, the hexahistidine tag was moved to the C-terminus. In the other construct, every second histidine residue in the hexahistidine tag was replaced by the more hydrophilic glutamate, resulting in a HEHEHE-tag. Both variants, denoted Z(HER)₂(:)₃₄₂-H₆ and (HE)₃-Z(HER)₂(:)₃₄₂, respectively, could be efficiently purified using IMAC and stably labeled with [⁹⁹(m)Tc(CO)₃](+) and were subsequently compared with the parental H₆-Z(HER)₂(:)₃₄₂ having an N-terminal hexahistidine tag. All three variants were demonstrated to specifically bind to HER2-expressing cells in vitro. The hepatic accumulation of radioactivity in a murine model was 2-fold lower with [⁹⁹(m)Tc(CO)₃](+)-Z(HER2:342)-H₆ compared to [⁹⁹(m)Tc(CO)₃](+)-H₆-Z(HER)₂(:)₃₄₂, and more than 10-fold lower with [⁹⁹(m)Tc(CO)₃](+)-(HE)₃-Z(HER)₂(:)₃₄₂. These differences translated into appreciably superior tumor-to-liver ratio for [⁹⁹(m)Tc(CO)₃](+)-(HE)₃-Z(HER)₂(:)₃₄₂ compared to the alternative conjugates. This information might be useful for development of other scaffold-based molecular imaging probes.
Engineered
affibody molecules can be used for high contrast in vivo molecular
imaging. Extending a recombinantly produced HER2 binding affibody
molecule with a hexa-histidine tag allows for convenient purification
by immobilized metal-ion affinity chromatography and labeling with
[99mTc(CO)3]+ but increases radioactivity
uptake in the liver. To investigate the impact of charge, lipophilicity,
and position on biodistribution, 10 variants of a histidine-based
tag was attached to a HER2 binding affibody molecule. The biochemical
properties and the HER2 binding affinity appeared to be similar for
all variants. In vivo, positive charge promoted liver uptake. For
N-terminally placed tags, lipophilicity promoted liver uptake and
decreased kidney uptake. Kidney uptake was higher for C-terminally
placed tags compared to their N-terminal counterparts. The variant
with the amino acid composition HEHEHE placed in the N-terminus gave
the lowest nonspecific uptake.
Affibody molecules are a class of small (∼7 kDa) robust scaffold proteins suitable for radionuclide molecular imaging in vivo. The attachment of a hexahistidine (His(6))-tag to the Affibody molecule allows facile purification by immobilized metal ion affinity chromatography (IMAC) but leads to high accumulation of radioactivity in the liver. Earlier, we have demonstrated that replacement of the His(6)-tag with the negatively charged histidine-glutamate-histidine-glutamate-histidine-glutamate (HEHEHE)-tag permits purification of Affibody molecules by IMAC, enables labeling with [(99m)Tc(CO)(3)](+), and provides low hepatic accumulation of radioactivity. In this study, we compared the biodistribution of cysteine-containing Affibody molecules site-specifically labeled with (111)In, (99m)Tc, and (125)I at the C-terminus, having a His(6)-tag at the N- or C-terminus or a HEHEHE-tag at the N-terminus. We show that the use of a HEHEHE-tag provides appreciable reduction of hepatic radioactivity, especially for radiometal labels. We hope that this information can also be useful for development of other scaffold protein-based imaging agents.
Aminoacyl tRNA synthetases (aaRSs) have long been viewed as mere housekeeping proteins and have therefore often been overlooked in drug discovery. However, recent findings have revealed that many aaRSs have non-canonical functions and several of the aaRSs have been linked to autoimmune diseases, cancer and neurological disorders. Deciphering these roles has been challenging due to a lack of tools to enable their study. To help solve this problem, we have generated recombinant high-affinity antibodies for a collection of thirteen cytoplasmic and one mitochondrial aaRSs. Selected domains of these proteins were produced recombinantly in Escherichia coli and used as antigens in phage display selections using a synthetic human single-chain fragment variable (scFv) library. All targets yielded large sets of antibody candidates that were validated through a panel of binding assays against the purified antigen. Furthermore, the top performing binders were tested in immunoprecipitation followed by mass spectrometry (IP-MS) for their ability to capture the endogenous protein from mammalian cell lysates. For antibodies targeting individual members of the multi-tRNA synthetase complex (MSC), we were able to detect all members of the complex, co-immunoprecipitating with the target, in several cell types. The functionality of a sub-set of binders for each target was also confirmed using immunofluorescence. The sequences of these proteins have been deposited in publicly available databases and repositories. We anticipate this open source resource, in the form of high quality recombinant proteins and antibodies, will accelerate and empower future research of the role of aaRSs in health and disease.
Affibody molecules are a class of small (ca.7 kDa) robust scaffold proteins with high potential as tracers for radionuclide molecular imaging in vivo. Incorporation of a cysteine-containing peptide-based chelator at the C terminus provides an opportunity for stable labelling with the radionuclide (99m)Tc. The use of a GGGC chelator at the C terminus has provided the lowest renal radioactivity retention of the previously investigated peptide-based chelators. Previously, it has also been demonstrated that replacement of the His(6)-tag with the negatively charged histidine-glutamate-histidine-glutamate-histidine-glutamate (HEHEHE)-tag permits purification of affibody molecules by immobilized metal ion affinity chromatography (IMAC) and provides low hepatic accumulation of radioactivity of conjugates site-specifically labelled at the C terminus using several different nuclides. We hypothesized that the combination of a HEHEHE-tag at the N terminus and a GGGC chelator at the C terminus of an affibody molecule would be a favourable format permitting IMAC purification and providing low uptake in excretory organs. To investigate this hypothesis, a (HE)(3)-Z(HER2:342)-GGGC affibody molecule was generated. It could be efficiently purified by IMAC and stably labelled with (99m)Tc. (99m)Tc-(HE)(3)-Z(HER2:342)-GGGC preserved specific binding to HER2-expressing cells. In NMRI mice, hepatic uptake of (99m)Tc-(HE)(3)-Z(HER2:342)-GGGC was lower than the uptake of the control affibody molecules, (99m)Tc-Z(HER2:2395)-VDC and (99m)Tc-Z(HER2:342)-GGGC. At 1 and 4 h after injection, the renal uptake of (99m)Tc-(HE)(3)-Z(HER2:342)-GGGC was 2-3-fold lower than uptake of (99m)Tc-Z(HER2:2395)-VDC, but it was substantially higher than uptake of (99m)Tc-Z(HER2:342)-GGGC. Further investigation indicated that a fraction of (99m)Tc was chelated by the HEHEHE-tag which caused a higher accumulation of radioactivity in the kidneys. Thus, a combination of a HEHEHE-tag and the GGGC chelator in targeting scaffold proteins was found to be undesirable in the case of (99m)Tc labelling due to a partial loss of site-specificity of nuclide chelation.
Overexpression of insulin-like growth factor-1 receptor (IGF-1R) in several cancers is associated with resistance to therapy. Radionuclide molecular imaging of IGF-1R expression in tumors may help in selecting the patients that will potentially respond to IGF-1R-targeted therapy. Affibody molecules are small (7 kDa) non-immunoglobulin-based scaffold proteins that are well-suited probes for radionuclide imaging. The aim of this study was the evaluation of an anti-IGF-1R affibody molecule labeled with technetium-99m using cysteine-containing peptide-based chelator GGGC at C-terminus. ZIGF1R:4551-GGGC was efficiently and stably labeled with technetium-99m (radiochemical yield 97 ± 3 %). 99mTc-ZIGF1R:4551-GGGC demonstrated specific binding to IGF-1R-expressing DU-145 (prostate cancer) and MCF-7 (breast cancer) cell lines and slow internalization in vitro. The tumor-targeting properties were studied in BALB/c nu/nu mice bearing DU-145 and MCF-7 xenografts. [99mTc(CO)3]+-(HE)3-ZIGF1R:4551 was used for comparison. The biodistribution study demonstrated high tumor-to-blood ratios (6.2 ± 0.9 and 6.9 ± 1.0, for DU-145 and MCF-7, respectively, at 4 h after injection). Renal radioactivity concentration was 16-fold lower for 99mTc-ZIGF1R:4551-GGGC than for [99mTc(CO)3]+-(HE)3-ZIGF1R:4551 at 4 h after injection. However, the liver uptake of 99mTc-ZIGF1R:4551-GGGC was 1.2- to 2-fold higher in comparison with [99mTc(CO)3]+-(HE)3-ZIGF1R:4551. A possible reason for the elevated hepatic uptake of 99mTc-ZIGF1R:4551-GGGC is a high lipophilicity of amino acids in the binding site of ZIGF1R:4551, which is not compensated in 99mTc-ZIGF1R:4551-GGGC. In conclusion, 99mTc-ZIGF1R:4551-GGGC can visualize the IGF-1R expression in human tumor xenografts and provides low retention of radioactivity in kidneys. Further development of this imaging agent should include molecular design aimed at reducing the hepatic uptake.
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