From the Cover: A new tubulin-binding site and pharmacophore for microtubule-destabilizing anticancer drugs

The recent success of antibody–drug conjugates (ADCs) in the treatment of cancer has led to a revived interest in microtubule-destabilizing agents. Here, we determined the high-resolution crystal structure of the complex between tubulin and maytansine, which is part of an ADC that is approved by the US Food and Drug Administration (FDA) for the treatment of advanced breast cancer. We found that the drug binds to a site on β-tubulin that is distinct from the vinca domain and that blocks the formation of longitudinal tubulin interactions in microtubules. We also solved crystal structures of tubulin in complex with both a variant of rhizoxin and the phase 1 drug PM060184. Consistent with biochemical and mutagenesis data, we found that the two compounds bound to the same site as maytansine and that the structures revealed a common pharmacophore for the three ligands. Our results delineate a distinct molecular mechanism of action for the inhibition of microtubule assembly by clinically relevant agents. They further provide a structural basis for the rational design of potent microtubule-destabilizing agents, thus opening opportunities for the development of next-generation ADCs for the treatment of cancer.Microtubule-targeting agents such as the taxanes and the vinca alkaloids represent a successful class of anticancer drugs (1). Vinblastine, for example, is a microtubule-destabilizing agent (MDA) that is widely used in combination therapy for the treatment of childhood and adult malignancies (2). The broad clinical application of MDAs, however, is hampered by their severe adverse effects (3). This problem has been very recently addressed by the use of antibody–drug conjugate (ADC) approaches, which have revived interest in the development of highly potent MDAs for therapeutic use (4–6).For several important MDAs, the molecular mechanism of action on tubulin and microtubules has so far remained elusive. Rhizoxin, for example, is a potent MDA that has been investigated in phase 2 clinical trials, but for reasons poorly understood, it has demonstrated only very limited clinical efficacy (7). At the molecular level, it is well established that rhizoxin interferes with the binding of vinblastine to tubulin; however, the exact location of its binding site has been a matter of debate (8–10). Interestingly, biochemical and mutagenesis data suggest that the structurally unrelated MDA maytansine (9, 11), which is part of an ADC that was recently approved by the FDA for the treatment of advanced breast cancer (11, 12), and the phase 1 drug PM060184 (13, 14) (Fig. 1A) share a common tubulin-binding site with rhizoxin (9, 13, 14). These two latter drugs have also been reported to interfere with the binding of vinblastine; however, as for rhizoxin, the exact binding sites and modes of action of maytansine and PM060184 have not been elucidated (9, 14–16).Open in a separate windowFig. 1.Structure of the tubulin–rhizoxin F complex. (A) Chemical structures of rhizoxin F, maytansine, and PM060184. (B) Overall view of the T₂R-TTL–rhizoxin F complex. Tubulin (gray), RB3 (light green), and TTL (violet) are shown in ribbon representation; the MDA rhizoxin F (orange) and GDP (cyan) are depicted in spheres representation. As a reference, the vinblastine structure (yellow, PDB ID no. 1Z2B) is superimposed onto the T₂R complex. (C) Overall view of the tubulin–rhizoxin F interaction in two different orientations. The tubulin dimer with bound ligand (α-tubulin-2 and β-tubulin-2 of the T₂R-TTL–rhizoxin F complex) is shown in surface representation. The vinblastine structure is superimposed onto the β-tubulin chain to highlight the distinct binding site of rhizoxin F. All ligands are in sphere representation and are colored in orange (rhizoxin F), cyan (GDP), and yellow (vinblastine). (D) Close-up view of the interaction observed between rhizoxin F (orange sticks) and β-tubulin (gray ribbon). Interacting residues of β-tubulin are shown in stick representation and are labeled.To establish the exact tubulin-binding site of rhizoxin, maytansine, and PM060184 and to clarify their specific interactions with the protein, we have investigated the structures of the corresponding ligand–tubulin complexes by X-ray crystallography. Our data reveal a new tubulin-binding site and pharmacophore for small molecules, and binding to this site is associated with a distinct molecular mechanism for the inhibition of microtubule formation.     

Synthetic control of mammalian-cell motility by engineering chemotaxis to an orthogonal bioinert chemical signal

Directed migration of diverse cell types plays a critical role in biological processes ranging from development and morphogenesis to immune response, wound healing, and regeneration. However, techniques to direct, manipulate, and study cell migration in vitro and in vivo in a specific and facile manner are currently limited. We conceived of a strategy to achieve direct control over cell migration to arbitrary user-defined locations, independent of native chemotaxis receptors. Here, we show that genetic modification of cells with an engineered G protein-coupled receptor allows us to redirect their migration to a bioinert drug-like small molecule, clozapine-N-oxide (CNO). The engineered receptor and small-molecule ligand form an orthogonal pair: The receptor does not respond to native ligands, and the inert drug does not bind to native cells. CNO-responsive migration can be engineered into a variety of cell types, including neutrophils, T lymphocytes, keratinocytes, and endothelial cells. The engineered cells migrate up a gradient of the drug CNO and transmigrate through endothelial monolayers. Finally, we demonstrate that T lymphocytes modified with the engineered receptor can specifically migrate in vivo to CNO-releasing beads implanted in a live mouse. This technology provides a generalizable genetic tool to systematically perturb and control cell migration both in vitro and in vivo. In the future, this type of migration control could be a valuable module for engineering therapeutic cellular devices.The ability of many cell types to migrate long distances within the body and specifically localize to target sites of action is critical for their proper function. For example, immune cells rapidly home to sites of infection, concentrating their powerful cytotoxic and proinflammatory activities for maximum efficacy while limiting damage to healthy tissue. In morphogenesis, cells undergo a complex stereotyped process involving migration as well as proliferation, differentiation, and programmed cell death to produce fully developed multicellular structures. In wound healing and regenerative processes, stem and progenitor cells home to injured tissues from nearby sites—as well as from distant locations including the bone marrow—to provide a stream of new cells to replenish and provide trophic support to old and damaged cells.Cell migration is also an important factor to consider in the use of cells as therapeutic agents. The use of cells for the treatment of a growing array of diseases including cancer, autoimmunity, and chronic wounds is currently being explored (1–6). The appropriate and efficient localization of therapeutic cells to sites of disease has been identified as an important factor for successful cell-based therapy (7–17). However, preclinical studies and clinical trials to date have shown that the homing to sites of disease of many cell types commonly used as therapeutics is frequently impaired or limited, especially after ex vivo expansion of cells in culture (7, 12, 18, 19).The ability to redirect the migration of cells to any user-specified location in the body would be a powerful enabling technology for basic research as well as for future applications, but there are currently few easily generalizable strategies to accomplish this goal. We conceived of an approach to direct cellular homing to small molecules by expressing, in motile cells, engineered G protein-coupled receptors (GPCRs) called receptors activated solely by a synthetic ligand (RASSLs) (20, 21).RASSLs are engineered to be unresponsive to endogenous ligands but can be activated by pharmacologically inert orthogonal small molecules (Fig. 1A). Versions of these receptors exist for the three major GPCR signaling pathways (Gαs-, Gαi-, and Gαq-coupled receptors), and the design of a new arrestin-biased variant has recently been reported (21, 22). Because GPCRs control many important physiological functions, including cell migration, we hypothesized that, by expressing these engineered receptors in motile cells, we could develop a general strategy for establishing user control over cell homing (Fig. 1B). Here, we use a family of second-generation RASSLs, known as designer receptors exclusively activated by a designer drug (DREADDs), that are activated only by the small molecule clozapine-N-oxide (CNO), an inert metabolite of the FDA-approved antipsychotic drug clozapine (Fig. S1) (20). CNO is highly bioavailable in rodents and humans, lacks affinity for any known receptors, channels, and transporters, and does not cause any appreciable physiological effects when systemically administered in normal mice (20, 23, 24).Open in a separate windowFig. 1.Engineered Gαi-coupled GPCRs Di3 and Di mediate cytoskeletal changes and chemotaxis of HL-60 neutrophils in response to CNO. (A) RASSLs are engineered GPCRs that interact orthogonally with a bioinert small-molecule drug. Natural ligands do not interact with the engineered receptors, and the bioinert drug that activates the engineered receptors does not interact with native receptors. (B) We tested whether certain second-generation RASSLs known as DREADDs could mediate cell motility. (C) Changes in electrical impedance that result from cell spreading in response to drug or ligand are detected by an electrode array. HL-60 neutrophils transiently transfected to express engineered GPCRs were plated on fibronectin-coated impedance assay plates and stimulated with vehicle control, 100 nM fMLP (positive control chemoattractant) or 100 nM CNO. All cells responded to fMLP whereas only Di3- or Di-expressing cells responded to CNO. Mean ± SEM for n = 3 replicates is shown. (D) Cell migration of HL-60 neutrophils transiently transfected with engineered GPCRs was quantitated in a porous transwell Boyden-chamber assay. All cells migrated in response to fMLP whereas only Di3- or Di-expressing cells migrated in response to CNO. Drug concentrations used: 100 nM CNO, 100 nM fMLP. Mean ± SEM for n = 3 replicates is shown. (E) Polarization and cell migration in neutrophils involves Rac and PI3K activation. Di-expressing HL-60 neutrophils were treated with 100 nM fMLP or 100 nM CNO before immunoblotting for phosphorylated Akt and phosphorylated PAK as readouts for PI3K and Rac activity, respectively. Peak levels of phospho-Akt and phospho-PAK are shown for each condition. Both were increased by CNO stimulation in Di cells but not in control cells (P < 0.01 by Student t test). Stimulation with fMLP increased phospho-Akt and phospho-PAK levels in both Di and control cells (P < 0.01 by Student t test), but Di cells showed higher peak levels of phospho-Akt than did control cells (P < 0.01 by Student t test). Three (for CNO) or four (for fMLP) independent experiments were performed and mean ± SEM are shown.     

Robot‐assisted laparoscopic retroperitoneal lymph node dissection for left clinical stage I non‐seminomatous germ cell testicular cancer: Focus on port placement and surgical technique

The aim of our report was to describe the feasibility of robotic retroperitoneal lymph node dissection in the contemporary era. We suggest the linear port location and 90° robotic docking as the main key to minimizing instrument clashing and improving the range of surgical accessibility.     

Feasibility of full-thickness gastric resection using master and slave transluminal endoscopic robot and closure by overstitch: a preclinical study

Background

Gastric submucosal tumors are often treated by laparoscopic wedge resection. This study aimed to examine the feasibility of gastric full-thickness resection through a totally endoscopic approach using the master and slave transluminal endoscopic robot (MASTER), and closure of the luminal defect with an endoscopic suturing device.

Methods

The operation was performed in two live porcine models under general anesthesia. First, the anterior wall of the stomach was slung to the abdominal wall using a percutaneous suturing device. An imaginary 5-cm lesion was marked using a needle knife. After the initial mucosal incision was made using an IT knife, the MASTER was introduced through a long overtube. A circumferential mucosal incision was completed with the MASTER to expose the muscularis propria which was grasped and incised to the serosal layer by electrocautery applied through the hook of the MASTER. The full-thickness resection of the gastric wall was completed with retraction using the grasper and dissection using the hook. While the defect was being created, the luminal space was maintained with traction of the percutaneous sutures. The defect was closed with suture plication using an Apollo Overstitch device.

Results

Two full-thickness gastric resections were performed in two nonsurvival porcine models (body weight = 30 and 35 kg, respectively) using the MASTER. The total procedure time was 56 min for the first model and 70 min for the second model. The luminal view was maintained during the whole procedure, and there was no damage to surrounding organs throughout the whole procedure. The gastric defects were closed successfully using Overstitch, with satisfactory gastric distension and no gas leakage afterward.

Conclusion

The current experiment demonstrated the feasibility and safety of a totally endoscopic approach for the treatment of gastric submucosal tumors: full-thickness resection with the MASTER and successful closure of the defect using Overstitch.     

Energy-dependent accumulation of norfloxacin and porin expression in clinical isolates of Klebsiella pneumoniae and relationship to extended-spectrum beta-lactamase production

The relationships between porin deficiency, active efflux of fluoroquinolones, and extended-spectrum beta-lactamase (ESBL) production were determined for 53 clinical isolates of Klebsiella pneumoniae. Thirty-two ESBL-positive strains (including 22 strains expressing porins and 10 strains lacking porins) and 21 ESBL-negative strains were evaluated. Active efflux of norfloxacin was defined as a >/=50% increase in the accumulation of norfloxacin in the presence of carbonyl cyanide m-chlorophenylhydrazone (CCCP) in comparison with the corresponding basal value in the absence of CCCP. The quinolone resistance-determining regions of both gyrA and parC from 13 strains, representing all isolates with different porin profiles and with or without active efflux, were determined. Porin loss was significantly more common among ESBL-positive strains (10 of 32 [31.2%]) than among ESBL-negative strains (0 of 2 [0%]) (P < 0.01). Active efflux was observed in 7 of 10 (70%) strains lacking porins and in 4 of 43 (9.3%) strains producing porins (P < 0.001). The 11 strains showing active efflux corresponded to 3 of 21 (14.3%) ESBL-negative strains and 8 of 32 (25.5%) ESBL-positive strains (P > 0.05). Basal values of norfloxacin accumulation were higher in strains lacking active efflux than in those that had this mechanism (P < 0.05). In the absence of topoisomerase changes, the contribution of either porin loss or active efflux to fluoroquinolone resistance in K. pneumoniae was negligible. It is concluded that among K. pneumoniae strains of clinical origin, porin loss was observed only in those producing ESBL, and that a significant number of porin-deficient strains also expressed active efflux of norfloxacin. In terms of fluoroquinolone resistance, both mechanisms are significant only in the presence of topoisomerase modifications.     

Measuring symptom prevalence, severity and distress of cancer survivors

The purpose of this paper is to describe patients’ self-reported symptom occurrence, symptom intensity and symptom distress at post-treatment of cancer therapy. A total of 243 outpatients with heterogeneous solid tumours within 12 months following the completion of initial cancer treatment (chemotherapy or radiotherapy) were assessed using the Chinese version of the Memorial Symptom Assessment Scale (MSAS). The mean age of the sample was 54.2 ± 12 and over half (57.6%) were women. The most common diagnoses were breast cancer (26.3%) and colon cancer (23.5%). The median number of symptoms per patient was 8 (range 0–23 symptoms) and the most prevalent were dry mouth (49.8%), lack of energy (46.9%), worry (39.1%), pain (35%) and feeling drowsy (33.7%). The mean symptom severity and distress scores measured on the MSAS were 1.92 ± 0.2 (range 1.7–2.3) and 1.37 ± 0.3 (.9–2), respectively. The prevalence of certain symptoms was influenced by the primary site of cancer. Pain, worrying and difficulty in swallowing were the most clinically important symptoms. In conclusion, intense physical and psychological symptoms were highly prevalent and distressing to cancer survivors. Comprehensive symptoms assessment is a requisite toward effective symptom control.     

Influência da dose de propofol e dos componentes sanguíneos na duração das convulsões elétricas em eletroconvulsoterapia

Background and objectives

Propofol is commonly employed as a hypnotic agent to perform electroconvulsive therapy, but it exhibits also anticonvulsant properties. The main objective was to study the effect of the weight‐adjusted dose of propofol on duration of the electrical seizure. Secondary objectives were to study the effect of absolute dose of propofol on duration of electrical seizure, the effect of both absolute and weight‐adjusted doses on values of bispectral index, and the influence of blood chemistry on anticonvulsant effect.

Attitude Toward Organ Donation and Transplantation in Veterinary Students: A Multicenter and Stratified Study in Spain

Background

Veterinarians often hold decision-making positions in the public health care system and can therefore influence public opinion about organ donation and transplantation (ODT). The aim of this work was to analyze the attitude of Spanish veterinary students toward ODT, because they may influence public opinion in the future, and to determine the factors that condition it.

1000 trasplantes hepáticos consecutivos. Análisis descriptivo y evolución de un centro

Between 1991 and 2013, 1,000 liver transplantations were performed at Virgen del Rocio Hospital (Seville, Spain). A retrospective study was conducted, analyzing the characteristics of recipients and donors, indications, surgical technique, complications and survival in 2 different stages (1991-2002 vs. 2003-2013) coinciding with the implementation of the MELD scale as a prioritization model. The most frequent indication were of hepatopathy of hepatocellular origin in 48.8%. There was a significant increase in the indications for hepatocarcinoma (8.6% and 24.1% P = 0.03), and the rate of retransplantation (5.9% vs 9.6%, P = 0.04). There was a change in the age of donation, going from 27.7 years in 1990 to 62.9 years in 2012 (P = 0.001). The percentage of patients who did not require blood transfusion doubled (6.16 vs. 14.31%, P = .001). Survival of all patients after one, 5 and 10 years was 77, 63.5 and 51.3%, respectively.