The Beta 2 Adrenergic Receptor Antagonist Timolol Improves Healing of Combined Burn and Radiation Wounds.

In a scenario involving a nuclear detonation during war or a terrorist attack, acute radiation exposure combined with thermal and blast effects results in severe skin injury. Although the cutaneous injury in such a scenario may not be lethal, it may lead to inflammation, delayed wound healing and loss of the skin barrier, resulting in an increased risk of infection. In this study, we tested the potential use of timolol, a beta-adrenergic receptor antagonist, to improve epidermal wound closure after combined burn and radiation injury using an ex vivo human skin culture model. Daily application of 10 µ M timolol after combined injury (burn and 10 Gy ex vivo irradiation) increased wound epithelialization by 5-20%. In addition, exposure to 10 Gy significantly suppressed epidermal keratinocyte proliferation by 46% at 48 h postirradiation. Similar to what has been observed in a thermal burn injury, the enzyme phenylethanolamine N-methyltransferase (PNMT), which generates epinephrine, was elevated in the combined thermal burn and radiation wounds. This likely resulted in elevated tissue levels of this catecholamine, which has been shown to delay healing. Thus, with the addition of timolol to the wound to block the binding of locally generated epinephrine to the beta-adrenergic receptor, healing is improved. This work suggests that by antagonizing local epinephrine action within the wound, a beta-adrenergic receptor antagonist such as timolol may be a useful adjunctive treatment to improve healing in the combined burn and radiation injury.

Microarray analysis of port wine stains before and after pulsed dye laser treatment.

BACKGROUND AND OBJECTIVES: Neither the pathogenesis of port wine stain (PWS) birthmarks nor tissue effects of pulsed dye laser (PDL) treatment of these lesions is fully understood. There are few published reports utilizing gene expression analysis in human PWS skin. We aim to compare gene expression in PWS before and after PDL, using DNA microarrays that represent most, if not all, human genes to obtain comprehensive molecular profiles of PWS lesions and PDL-associated tissue effects. MATERIALS AND METHODS: Five human subjects had PDL treatment of their PWS. One week later, three biopsies were taken from each subject: normal skin (N); untreated PWS (PWS); PWS post-PDL (PWS + PDL). Samples included two lower extremity lesions, two facial lesions, and one facial nodule. High-quality total RNA isolated from skin biopsies was processed and applied to Affymetrix Human gene 1.0ST microarrays for gene expression analysis. We performed a 16 pair-wise comparison identifying either up- or down-regulated genes between N versus PWS and PWS versus PWS + PDL for four of the donor samples. The PWS nodule (nPWS) was analyzed separately. RESULTS: There was significant variation in gene expression profiles between individuals. By doing pair-wise comparisons between samples taken from the same donor, we were able to identify genes that may participate in the formation of PWS lesions and PDL tissue effects. Genes associated with immune, epidermal, and lipid metabolism were up-regulated in PWS skin. The nPWS exhibited more profound differences in gene expression than the rest of the samples, with significant differential expression of genes associated with angiogenesis, tumorigenesis, and inflammation. CONCLUSION: In summary, gene expression profiles from N, PWS, and PWS + PDL demonstrated significant variation within samples from the same donor and between donors. By doing pair-wise comparisons between samples taken from the same donor and comparing these results between donors, we were able to identify genes that may participate in formation of PWS and PDL effects. Our preliminary results indicate changes in gene expression of angiogenesis-related genes, suggesting that dysregulation of angiogenic signals and/or components may contribute to PWS pathology.

The differentially regulated genes TvQR1 and TvPirin of the parasitic plant Triphysaria exhibit distinctive natural allelic diversity.

BACKGROUND: Plant parasitism represents an extraordinary interaction among flowering plants: parasitic plants use a specialized organ, the haustorium, to invade the host vascular system to deprive host plants of water and nutrients. Various compounds present in exudates of host plants trigger haustorium development. The two most effective haustorium inducing factors (HIFs) known for the parasitic plant Triphysaria versicolor (T. versicolor) are peonidin, an antioxidant flavonoid, and 2,6-dimethoxybenzoquinone (DMBQ), an oxidative stress agent. To date, two genes involved in haustorium initiation in T. versicolor have been identified: TvQR1, a quinone oxidoreductase that generates the active HIF from DMBQ, and TvPirin, a transcription co-factor that regulates several other DMBQ- responsive and -non-responsive genes. While the expression of these genes in response to DMBQ is well characterized, their expression in response to peonidin is not. In addition, the pattern of polymorphisms in these genes is unknown, even though nucleotide changes in TvQR1 and TvPirin may have contributed to the ability of T. versicolor to develop haustoria. To gain insights into these aspects, we investigated their transcriptional responses to HIFs and non-HIF and their natural nucleotide diversity. RESULTS: Here we show that TvQR1 and TvPirin are transcriptionally upregulated by both DMBQ and peonidin in T. versicolor roots. Yet, while TvQR1 also responded to juglone, a non-HIF quinone with toxicity comparable to that of DMBQ, TvPirin did not. We further demonstrate that TvPirin encodes a protein shorter than the one previously reported. In the T. versicolor natural population of Northern California, TvQR1 exhibited remarkably higher molecular diversity and more recombination events than TvPirin, with the highest non-synonymous substitution rate in the substrate recognition and catalytic domain of the TvQR1 protein. CONCLUSION: Our results suggest that TvQR1 and TvPirin have most likely evolved highly distinct roles for haustorium formation. Unlike TvPirin, TvQR1 might have been under diversifying selection to maintain a diverse collection of polymorphisms, which might be related to the recognition of an assortment of HIF and non-HIF quinones as substrates for successful haustorial establishment in a wide range of host plants.

Concurrent HER2 vaccination and inhibition of kinase activity: safety and immunogenicity.

Passive immunotherapy with the monoclonal antibody trastuzumab and tyrosine kinase activity inhibition with lapatinib are HER2-targeted therapies used in the clinic for the treatment of HER2-overexpressing breast cancers. Unfortunately, the therapeutic efficacy of both these therapies is abolished by primary and acquired tumor resistance. Active immunotherapy against HER2, which, thanks to trastuzumab, is a clinically validated tumor-associated antigen, might provide an alternative therapeutic strategy for HER2-overexpressing breast cancers. This Phase I study of HER2 immunotherapy with concomitant lapatinib treatment in 12 patients with metastatic breast cancer resistant to trastuzumab demonstrates the feasibility and safety of concurrent vaccination against HER2 and inhibition of HER1 and HER2 kinases. However, it is inconclusive regarding the effect of lapatinib on the immune responses induced by dHER2/AS15; vaccination triggered variable levels of anti-HER2 antibodies in all the patients, but a HER2-specific T-cell response was detected in one patient only. Since the presence of Tregs in these patients was not assessed, it remains unclear whether lapatinib and/or Tregs account for the near absence of a T-cell response.

Genomic characterization of a three-dimensional skin model following exposure to ionizing radiation.

This study aimed at characterizing the genomic response to low versus moderate doses of ionizing radiation (LDIR versus MDIR) in a three-dimensional (3D) skin model, which exhibits a closer tissue complexity to human skin than monolayer cell cultures. EpiDermFT skin plugs were exposed to 0, 0.1 and 1 Gy doses of X-rays and harvested at 5 min, 3, 8 and 24 h post-irradiation (post-IR). RNA was interrogated for global gene expression alteration. Our results show that MDIR modulated a larger number of genes over the course of 24 h compared to LDIR. However, immediately and throughout the first 3h post-IR, LDIR modulated a larger number of genes than MDIR, mostly associated with cell-cell signaling and survival promotion. Significant modulation of pathways was detected only at 3 h post-IR in MDIR with induction of genes promoting apoptosis. Collectively, the data show different dynamics in the response to LDIR versus MDIR, especially in cell-cycle distribution. LDIR-exposed tissues showed signs of attempted cell-cycle re-entry as early as 3 h post-IR, but were arrested beyond 8 h at the G1/S checkpoint. At 24 h, cells appeared to accumulate at the G2/M checkpoint. MDIR-exposed tissues did not exhibit a prolonged G1/S arrest but rather a prolonged G2/M arrest, which was sustained at least up to 24 h. By 24 h cells exhibited signs of recovery in both LDIR- and MDIR-exposed tissues. In summary, the most pronounced difference in the initial cellular response to LDIR versus MDIR is the promotion of protection and survival in LDIR versus the promotion of apoptosis in MDIR.

Transcriptional response of ex vivo human skin to ionizing radiation: comparison between low- and high-dose effects.

Although human exposure to low-dose ionizing radiation can occur through a variety of sources, including natural, medical, occupational and accidental, the true risks of low-dose ionizing radiation are still poorly understood in humans. Here, the global transcriptional responses of human skin after ex vivo exposure to low (0.05 Gy) and high (5 Gy) doses of X rays and of time in culture (0 Gy) at 0, 2, 8 and 30 h postirradiation were analyzed and compared. Responses to low and high doses differed quantitatively and qualitatively. Differentially expressed genes fell into three groups: (1) unique genes defined as responsive to either 0.05 or 5 Gy but not both and also responsive to time in culture, (2) specific genes defined as responsive to either 0.05 or 5 Gy but not both and not responsive to time in culture, and (3) dose-independent responsive genes. Major differences observed in ex vivo irradiated skin between transcriptional responses to low or high doses were twofold. First, gene expression modulated by 0.05 Gy was transient, while in response to 5 Gy persistence of modified gene expression was observed for a limited number of genes. Second, neither TP53 nor TGFß target genes were modulated after exposure to an acute low dose, suggesting that the TP53-dependent DNA damage response either was not triggered or was triggered only briefly.

MUC1 and MUC4: switching the emphasis from large to small.

The MUC1 and MUC4 membrane mucins are each composed of a large alpha (α) and a small beta (ß) subunit. The α subunits are fully exposed at the cell surface and contain variable numbers of repeated amino acid sequences that are heavily glycosylated. In contrast, the ß subunits are much smaller and are anchored within the cell membrane, with their amino-terminal portions exposed at the cell surface and their carboxy-terminal tails facing the cytosol. Studies over the last several years are challenging the long-held belief that α subunits play the predominant role in cancer by conferring cellular properties that allow tumor cells to evade immune recognition and destruction. Indeed, the ß subunits of MUC1 and MUC4 have emerged as oncogenes, as they engage signaling pathways responsible for tumor initiation and progression. Thus, a switch in the emphasis from the large α to the small ß subunits offers attractive possibilities for successful clinical application. Such a focus shift is further supported by the absence of allelic polymorphism and variable glycosylation in the ß subunit as well as by the presence of the ß subunit in most MUC1 and MUC4 isoforms expressed by tumors. MUC1α, also known as CA15.3, is a Food and Drug Administration-approved serum biomarker for breast cancer, but its use is no longer recommended by the American Society of Clinical Oncology. However, comparison of ß subunit expression in normal and malignant breast tissues may offer a novel approach to the exploitation of membrane mucins as biomarkers, as MUC1ß-induced gene signatures with prognostic and predictive values in breast cancer have been reported. Preclinical studies with peptides that interfere with MUC1ß oncogenic functions also look promising.

Trastuzumab (Herceptin®): overcoming resistance in HER2-overexpressing breast cancer models.

Evaluation of: Fujimoto-Ouchi K, Sekiguchi F, Yamamoto K et al.: Preclinical study of prolonged administration of trastuzumab as combination therapy after disease progression during trastuzumab monotherapy. Cancer Chemother. Pharmacol. 66, 269-276 (2010). Trastuzumab, a humanized antibody targeted against human epidermal receptor (HER)2, is used in combination with chemotherapy to treat patients with breast cancers overexpressing HER2. Despite initial clinical responses, disease progresses in a significant proportion of patients treated with trastuzumab and chemotherapy. Evidence of resistance to trastuzumab has not deterred a widespread clinical practice in the treatment of metastatic breast cancer - at least before lapatinib entered the clinic - which consists of continued administration of trastuzumab in combination with another chemotherapeutic drug. At present, it is not known if patients benefit from this practice. The present preclinical study demonstrates that, in the MDA-MB-361 and KPL-4 HER2(+) breast cancer models, induced resistance to trastuzumab monotherapy can be overcome by a combination of trastuzumab and granulocyte colony stimulating factor or chemotherapy. The response to trastuzumab and granulocyte colony stimulating factor appears to involve the host's immune system and antibody-dependent cellular cytotoxicity. The mechanisms underlying the response to trastuzumab and chemotherapy remain unclear.

Single-molecule approach to understanding multivalent binding kinetics.

Multivalency results from the simultaneous binding of multiple ligands with multiple receptors. Understanding the effect of multivalency on binding kinetics in molecular and cellular systems may aid the development of new types of therapeutics or countermeasures to pathogen infection. Here, we describe a method using single-molecule dynamic force spectroscopy to determine the binding strength of antibody-protein complexes as a function of binding valency in a direct and simple measurement. We used the atomic force microscope to measure the force required to rupture a single complex formed by the MUC1 protein, a cancer indicator, and therapeutic antibodies that target MUC1. We will show that nanomechanical polymer tethers can be used in a new manner to count the number of biological bonds formed. Mechanical work will disrupt these bonds and can be used to quantify the overall kinetics. This ability to form, count, and dissociate biological bonds with nanomechanical forces provides a powerful method to study the physical laws governing the interactions of biological molecules.

Fundamentals of antibody-related therapy and diagnostics.

Antibodies for therapy and diagnostics form one of the fastest growing segments of the pharmaceutical market. The combination of hybridoma and recombinant DNA technologies have led to an increased production of monoclonal antibodies (MAbs), including fully human MAbs, that can be tailored for specific applications. With advances in imaging methods, MAbs are increasingly used as in vivo diagnostic tools. Therapeutic MAbs, used to treat cancer and autoimmune diseases, have proven beneficial in the clinic. An overview is presented of the history, current state and future perspectives of this emergent field.

111In-LLP2A-DOTA Polyethylene Glycol-Targeting {alpha}4{beta}1 Integrin: Comparative Pharmacokinetics for Imaging and Therapy of Lymphoid Malignancies.

UNLABELLED: N-[[4-[[[(2-ethylphenyl)amino]carbonyl]amino]phenyl]acetyl]-N(epsilon)-6-[(2E)-1-oxo-3-(3-pyridinyl-2-propenyl)]-l-lysyl-l-2-aminohexanedioyl-(1-amino-1-cyclohexane)carboxamide (LLP2A) is a high-affinity, high-specificity peptidomimetic ligand (inhibitory concentration of 50% = 2 pM) that binds the activated alpha4beta1 integrin found on a variety of malignant lymphoid cell lines. To better determine whether this ligand holds promise for imaging and therapy in lymphoid malignancies, 6 LLP2A derivatives, as LLP2A-1,4,7,10-tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid (LLP2A-DOTA) and LLP2A-DOTA-polyethylene glycol (LLP2A-DOTA-PEG), were designed, synthesized, and radiolabeled with (111)In. Comparative pharmacokinetic studies in mice with Raji B-cell lymphoma xenografts were then complemented by small-animal PET of the lead molecular LLP2A format using (64)Cu-LLP2A-11-bis(carboxymethyl)-1,4,8,11-tetraazabicyclo[6.6.2]hexadecane ((64)Cu-LLP2A-CB-TE2A). METHODS: LLP2A-DOTA and LLP2A-CB-TE2A were prepared using solid-phase synthesis; LLP2A-DOTA-PEG(2,000), LLP2A-DOTA-PEG(5,000), LLP2A-DOTA-PEG(10,000), (LLP2A-DOTA)(2)PEG(10,000), and (LLP2A-DOTA)(4)PEG(10,000) were prepared by PEGylation. (111)In radiolabeling of DOTA and (64)Cu radiolabeling of CB-TE2A conjugates yielded 370-1,850 and 3,700-7,400 kBq/microg (10-50 and 100-200 microCi/microg), respectively. The pharmacokinetics of the six (111)In radioconjugates were studied in vivo using biodistribution data (4 and 24 h) and whole-body autoradiography (24 h) in mice with Raji tumor xenografts. (64)Cu-LLP2A-CB-TE2A was imaged (4 and 24 h) on a small-animal PET scanner in the same mouse model. RESULTS: The highest tumor uptake in pharmacokinetic studies was obtained with LLP2A-DOTA and (LLP2A-DOTA)(4)-PEG(10,000). For (111)In-LLP2A-DOTA (1 nM) at 4 and 24 h after injection, ratios of tumor to blood and tumor to nontumor (normal) organ (T/NT) were 8 to 35:1 for all organs or tissue except the spleen, marrow, and kidney, which were between 2:1 and 1:1. Tetravalent (LLP2A-DOTA)(4)-PEG(10,000) (1.1 nM) had tumor uptake similar to the univalent LLP2A-DOTA but higher liver, marrow, and kidney uptake. The excellent T/NT of LLP2A was also demonstrated by small-animal PET with (64)Cu-LLP2A-CB-TE2A at both 4 and 24 h after injection; obvious spleen targeting was apparent, but little kidney or liver activity was observed. CONCLUSION: Of the conjugates investigated, the univalent, non-PEGylated ligand (111)In-LLP2A-DOTA exhibited the best T/NT ratios and showed the greatest potential for imaging of alpha4beta1 in human lymphoma. Furthermore, this univalent non-PEGylated LLP2A format, as (64)Cu-LLP2A-CB-TE2A, demonstrated excellent tumor targeting by small-animal PET and warrants further investigation as an agent for the study of alpha4beta1 expression in human lymphoid malignancies.

Recombinant expression of the beta-subunit of HLA-DR10 for the selection of novel lymphoma targeting molecules.

Selective high-affinity ligands (SHALs) were selected as substitutes for monoclonal antibodies (mAbs) to deliver radioisotopes to malignant tumors. Because a SHAL (5 KD) is considerably smaller in comparison to an antibody (150 KD), a significant therapeutic index (TI) enhancement for radioimmunotherapy (RIT) is anticipated. The antibody-antigen (Ab-Ag) model system chosen for the development of SHALs consists of Lym-1, a MAb with proven selectivity in non-Hodgkin's lymphoma (NHL) patients and its well-characterized Ag, the beta subunit of HLA DR10. Whereas Lym-1 is readily available, the subunit of HLA-DR10 is not. Native, heterodimeric (alpha and beta subunits) HLA-DR10 can be purified from Raji cells, which are known to overexpress this Ag. Inconsistent homogeneity between preparations of HLA-DR10 solubilized in the presence of detergents prompted us to express a recombinant form of the beta subunit of HLA-DR10 in Escherichia coli. Negligible production yields (

Selective high-affinity ligand antibody mimics for cancer diagnosis and therapy: initial application to lymphoma/leukemia.

PURPOSE: More than two decades of research and clinical trials have shown radioimmunotherapy to be a promising approach for treating various forms of cancer. Lym-1 antibody, which binds selectively to HLA-DR10 on malignant B-cell lymphocytes, has proved to be effective in delivering radionuclides to non-Hodgkin's lymphoma and leukemia. Using a new approach to create small synthetic molecules that mimic the targeting properties of the Lym-1 antibody, a prototype, selective high-affinity ligand (SHAL), has been developed to bind to a unique region located within the Lym-1 epitope on HLA-DR10. EXPERIMENTAL DESIGN: Computer docking methods were used to predict two sets of small molecules that bind to neighboring cavities on the beta subunit of HLA-DR10 surrounding a critical amino acid in the epitope, and the ligands were confirmed to bind to the protein by nuclear magnetic resonance spectroscopy. Pairs of these molecules were then chemically linked together to produce a series of bidentate and bisbidentate SHALs. RESULTS: These SHALs bind with nanomolar to picomolar K(d)'s only to cell lines expressing HLA-DR10. Analyses of biopsy sections obtained from patients also confirmed that SHAL bound to both small and large cell non-Hodgkin's lymphomas mimicking the selectivity of Lym-1. CONCLUSIONS: These results show that synthetic molecules less than 1/50th the mass of an antibody can be designed to exhibit strong binding to subtle structural features on cell surface proteins similar to those recognized by antibodies. This approach offers great potential for developing small molecule therapeutics that target other types of cancer and disease.

Recombinant antibodies: from the laboratory to the clinic.

The development of recombinant antibodies has facilitated the exploitation of the Ab-Ag interaction specificity for targeted therapies. A fully human antibody, with custom integrated designs, can be obtained in one-third the time, compared to development of antibodies by hybridoma technology. Recombinant antibodies can be tailored for specific applications, "armed" with cytotoxic agents in a controllable fashion, and used for extracellular and intracellular targeting. Multitargeted and combination therapies are rapidly evolving for the treatment of cancer. Antibody therapeutics, costly to develop and produce, have proven beneficial in the clinic.

Characterization of MUC1 glycoprotein on prostate cancer for selection of targeting molecules.

MUC1 glycoprotein that is overexpressed in aberrant forms in epithelial cancers has been used for diagnosis, staging and therapy. As normal prostate and prostate cancer tissues express MUC1, it represents a potential target, but MUC1 epitopes specific to prostate cancer have not been well characterized. In order to assess MUC1 epitopes in prostate cancer, and their correlation with Gleason grades, binding of 7 well-characterized anti-MUC1 monoclonal antibodies (MAbs) (BrE-3, SM3, BC2, EMA, B27.29, HMFG-1 and NCL MUC1 core), were studied on a prostate tissue microarray. This microarray contained 197 prostate tissue cores representing: i) normal/benign prostate; ii) prostatic intraepithelial neoplasia and Gleason grades 1 and 2; and iii) Gleason grades 3-5. These MAbs bind the MUC1 extracellular domain, but have variable sensitivity to MUC1 glycosylation. To further characterize the effect of glycosylation on their binding, MAb reactivities with unglycosylated MUC1 core peptide and breast and prostate cancer cell lysates were compared. These studies demonstrated strong binding of BrE-3, BC2 and EMA to the peptide core and recognition by BrE-3, SM3, BC2 and EMA of hypoglycosylated MUC1. The results for the microarray indicated that higher Gleason grades were associated with markedly increased cellular staining by MAbs that preferentially recognize less glycosylated MUC1 (BrE-3, p<0.001; SM3, p<0.004; EMA, p=0.009; and BC2, p<0.001). Staining by MAbs that bind preferentially to hyperglycosylated MUC1 (B27.29, p=0.33; HMFG-1, p=0.89; and NCL MUC1 core, p=0.96) did not correlate with Gleason grade. These results demonstrated that hypoglycosylated MUC1 expression increased with Gleason grade, thus supporting the targeting of hypoglycosylated MUC1 epitopes in prostate cancer for more specific imaging and therapy applications.

Monospecific bivalent scFv-SH: effects of linker length and location of an engineered cysteine on production, antigen binding activity and free SH accessibility.

Development of tumor targeting pharmaceuticals on a modular platform is an attractive paradigm. Design choices for bispecific (anti-tumor and anti-chelate) pretargeting molecules are increased by the use of scFvs. Because a scFv is monovalent and small in size, its functional affinity and in vivo residence time can be improved through multimerization. ScFv multimers can be covalent or non-covalent. In vivo studies indicate that covalent scFv multimers are preferable. Attachment of scFv modules to scaffolds offers a wide range of possibilities for size and valency. A free thiol introduced at the C terminal end of a scFv (scFv-SH) allows for site-specific covalent attachment to a PEG scaffold without interfering with its antigen (Ag) binding. Although in theory, multimerization of 3 or 4 scFvs can be achieved by direct conjugation, as scFv-SH, to a tri or tetrafunctionalized PEG, it is not a practical option since homogeneous tri and tetrafunctionalized PEG are not readily available. However, the generation of (scFv)(3-4)-PEG molecules through attachment of combinations of di-scFv-SH (tandemly expressed scFvs) and scFv-SH or 2 di-scFv-SH to a bifunctional PEG is a sound approach that also allows for better control of the scFv-PEG conjugate molecular composition. Optimization of the molecular format of the di-scFv-SH module for production as soluble proteins in E. coli, Ag binding and conjugation is reported in this study. ScFvs in the VH-VL format were used for the di-scFv constructs since Fv domain inversion to VL-VH, while not yielding more protein, also abolished Ag binding. The effects on production yield, Ag binding and conjugation potential of the scFv joining linker length and the presence and location of an engineered cysteine were assessed in vitro. Our data indicate that for di-scFv-SH, an increase of the scFv joining linker length results in higher production and better Ag binding; a 20 aa long linker (G(4)S)(4) was the longest linker tested. For the engineered cysteine, three locations were tested; within the scFv joining linker, at the C terminus upstream of the E Tag and as the carboxy terminal aa. The accessibility of the free SH assessed by conjugation of di-scFv-SH to HRP-Mal demonstrated that di-scFv-HRP conjugates are formed with comparable efficiencies when the cysteine is located at the scFv carboxy end. This empirical work provides a framework for the development of bispecific scFv multimers via site-specific attachment of scFv-SH and di-scFv-SH modules to a scaffold.

Dynamic force spectroscopy of parallel individual Mucin1-antibody bonds.

We used atomic force microscopy to measure the binding forces between Mucin1 (MUC1) peptide and a single-chain variable fragment (scFv) antibody selected from a scFv library screened against MUC1. This binding interaction is central to the design of molecules used for targeted delivery of radioimmunotherapeutic agents for prostate and breast cancer treatment. Our experiments separated the specific binding interaction from nonspecific interactions by tethering the antibody and MUC1 molecules to the atomic force microscope tip and sample surface with flexible polymer spacers. Rupture force magnitude and elastic characteristics of the spacers allowed identification of the rupture events corresponding to different numbers of interacting proteins. We used dynamic force spectroscopy to estimate the intermolecular potential widths and equivalent thermodynamic off rates for monovalent, bivalent, and trivalent interactions. Measured interaction potential parameters agree with the results of molecular docking simulation. Our results demonstrate that an increase of the interaction valency leads to a precipitous decline in the dissociation rate. Binding forces measured for monovalent and multivalent interactions match the predictions of a Markovian model for the strength of multiple uncorrelated bonds in a parallel configuration. Our approach is promising for comparison of the specific effects of molecular modifications as well as for determination of the best configuration of antibody-based multivalent targeting agents.

Enhancement of the therapeutic index: from nonmyeloablative and myeloablative toward pretargeted radioimmunotherapy for metastatic prostate cancer.

PURPOSE: New strategies that target selected molecular characteristics and result in an effective therapeutic index are needed for metastatic, hormone-refractory prostate cancer. EXPERIMENTAL DESIGN: A series of preclinical and clinical studies were designed to increase the therapeutic index of targeted radiation therapy for prostate cancer. (111)In/90Y-monoclonal antibody (mAb), m170, which targets aberrant sugars on abnormal MUC1, was evaluated in androgen-independent prostate cancer patients to determine the maximum tolerated dose and efficacy of nonmyeloablative radioimmunotherapy and myeloablative combined modality radioimmunotherapy with paclitaxel. To enhance the tumor to liver therapeutic index, a cathepsin degradable mAb linkage ((111)In/90Y-peptide-m170) was used in the myeloablative combined modality radioimmunotherapy protocol. For tumor to marrow therapeutic index improvement in future studies, anti-MUC1 scFvs modules were developed for pretargeted radioimmunotherapy. Anti-MUC1 and anti-DOTA scFvs were conjugated to polyethylene glycol scaffolds tested on DU145 prostate cancer cells and prostate tissue arrays, along with mAbs against MUC1 epitopes. RESULTS: The nonmyeloablative maximum tolerated dose of 90Y-m170 was 0.74 GBq/m2 for patients with not more than 10% axial skeleton involvement. Metastatic prostate cancer was targeted in all 17 patients; mean radiation dose was 10.5 Gy/GBq and pain response occurred in 7 of 13 patients reporting pain. Myeloablative combined modality radioimmunotherapy with 0.4 GBq/m2 of 90Y-peptide-m170 and paclitaxel showed therapeutic effects in 4 of 6 patients and 30% less radiation to the liver per unit of activity. Neutropenia was dose limiting without marrow support and patient eligibility was a major limitation to dose escalation. Hypoglycosylated MUC1 epitopes were shown to be abundant in prostate cancer and to increase with disease grade. Anti-MUC1 scFvs binding to prostate cancer tissue and live cells were developed into di-scFv binding modules. CONCLUSIONS: The therapeutic index enhancement for prostate radioimmunotherapy was achieved in clinical studies by the addition of cathepsin cleavable linkers to 90Y-conjugated mAbs and the use of paclitaxel. However, the need for marrow support in myeloablative combined modality radioimmunotherapy restricted eligible patients. Therefore, modular pretargeted radioimmunotherapy, aiming at improving the tumor to marrow therapeutic index, is being developed.

Characterization of site-specific ScFv PEGylation for tumor-targeting pharmaceuticals.

New radiopharmaceuticals are possible using site-specific conjugation of small tumor binding proteins and poly(ethylene glycol) (PEG) scaffolds to provide modular multivalent, homo- or heterofunctional cancer-targeting molecules having preferred molecular size, valence, and functionality. Residence time in plasma can be optimized by modification of the size, number, and charge of the protein units. However, random PEG conjugation (PEGylation) of these small molecules via amine groups has led to variations of structural conformation and binding affinity. To optimize PEGylation, scFvs have been recombinantly produced in a vector that adds an unpaired cysteine (c) near the scFv carboxy terminus (scFv-c), thus providing a specific site for thiol conjugation. To evaluate the general applicability of this unpaired cysteine for PEGylation of scFv-c, conjugation efficiency was determined for four different scFvs and several PEG molecules having thiol reactive groups. The effect of the PEG molecular format on scFv-c PEG malignant cell binding was also addressed. ScFvs produced as scFv-c and purified by anti E-TAG affinity chromatography were conjugated using PEG molecules with maleimide (Mal) or o-pyridyl disulfide (OPSS). Conjugations were performed at pH 7.0, with 2 molar excess TCEP/scFv and PEG-(Mal) or PEG-OPSS, using 5:1 (PEG/scFv). PEG-Mal conjugation efficiency was also evaluated with 1:5 (PEG/scFv). PEGylation efficiency was determined for each reaction by quantitation of the products on SDS-PAGE. ScFv-c conjugation with unifunctional maleimide PEGs resulted in PEG conjugates incorporating 30-80% of the scFv-c, but usually above 50%. Efficiency of scFv-c conjugation to both functional groups of the bifunctional PEG-(Mal)2 varied between the PEG and scFv-c molecules studied. A maximum of 45% of scFv-c protein was conjugated as PEG- (scFv-c)2 using the smallest PEG-(Mal)2 (2 kDa). No significant increase in scFv-c conjugation was observed by the use of greater than a 5 molar excess of PEG/scFv-c. Under the same conjugation conditions, PEG as OPSS yielded less than 10% PEG-scFv-c. PEG-(scFv)2 conjugates had increased binding in ELISA using malignant cell membranes, when compared with unmodified scFv-c. PEGylated-scFv binding was comparable with unmodified scFv-c. In summary, scFv-c can be PEGylated in a site-specific manner using uni- or bivalent PEG-Mal, either linear or branched. ScFv-c was most efficiently conjugated to smaller PEG-Mal molecules, with the smallest, 2 kDa PEG-Mal, usually PEGylating 60-90% of the scFv-c. ScFv-c conjugation to form PEG-(scFv-c)2 reached greatest efficiency at 45%, and its purified form demonstrated greater binding than the corresponding scFv-c.

Production of soluble ScFvs with C-terminal-free thiol for site-specific conjugation or stable dimeric ScFvs on demand.

ScFv recombinant antibody fragments can provide specific tumor binding modules for targeting drugs. In the process of building multimeric tumor targeting pharmaceuticals, a prerequisite is the conservation of functional scFv antigen binding domains, thereby excluding scFv random conjugation to a carrier molecule or to another scFv. The pCANTAB 5E phage display/expression vector was genetically engineered to express any scFv gene as scFv with an additional C-terminal cysteine (scFv-Cys) such that the specific conjugation site is removed from the binding domain. Selected scFvs derived from an anti-MUC-1 scFv phage library were expressed in pCANTAB 5E and its modified version pCANTAB 5E Cys vectors, and compared for key characteristics. Production yields of scFv and scFv-Cys in shaker flask and biofermentor were compared. In the absence of a reducing agent, stable dimers (covalent scFv homodimers (scFv-Cys)2) were the major form of scFv-Cys. These diabodies provided substantial signal enhancement for immunohistochemical staining of tissues. In the presence of a reducing agent, scFv-Cys molecules remained monomeric, with the free SH available for conjugation to a PEG(maleimide)2 scaffold to form immunoreactive PEG(scFv)2 bioconjugates. ScFv expression from pCANTAB 5E Cys allowed for the production of soluble scFv-Cys protein from E.coli, either as stable scFv-Cys or (scFv-Cys)2. ScFv-Cys can be used for conjugation to PEG to form bivalent PEG (scFv-Cys)2 molecules or used as (scFv-Cys)2 for increased sensitivity in IHC.