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MOV file - 6MB, Effect of Pyr1 on microtubule dynamic instability - Time-lapse microscopy after 2 hours of incubation, on GFP-EB3 HeLa cells treated with DMSO (control), 5 muM, 10 muM or 25 muM Pyr1, as indicated. 4.Supplementary information

PDF file - 486K, Analysis of the consequence of actin filaments depolymerization on Pyr1 -induced formation of Detyr-microtubules

PDF file - 212K, Effect of Pyr1 treatment on the number and on the size of EB1 comets in HeLa cells

PDF file - 173K, Characterization of Pyr1 (Pyr1) effects on the inhibition of LIMKs activity in vitro

PDF file - 487K, Effects of Pyr1 structural analogues on F-actin organization, on Detyr-microtubules generation, and on in cellulo cofilin phosphorylation

PDF file - 252K, Effect of Pyr1 on NEK11 and MLK1 activity

PDF file - 253K

PDF file - 173K, Effect of LIMK down regulation on Detyr-tubulin levels

Racism is now widely recognized as a fundamental cause of health inequali­ties in the United States. As such, health scholars have rightly turned their attention toward examining the role of struc­tural racism in fostering morbidity and mortality. However, to date, much of the empirical structural racism-health dispari­ties literature limits the operationalization of structural racism to a single domain or orients the construct around a White/ Black racial frame. This operationaliza­tion approach is incomprehensive and overlooks the heterogeneity of historical and lived experiences among other racial and ethnic groups.To address this gap, we present a theoreti­cally grounded framework that illumi­nates core mutually reinforcing domains of structural racism that have stratified opportunities for health in the United States. We catalog instances of structural discrimination that were particularly con­straining (or advantageous) to the health of racial and ethnic groups from the late 1400s to present. We then illustrate the utility of this framework by applying it to American Indians or Alaska Natives and discuss the framework’s broader implica­tions for empirical health research. This framework should help future scholars across disciplines as they identify and interrogate important laws, policies, and norms that have differentially constrained opportunities for health among racial and ethnic groups.Ethn Dis. 2021;31(Suppl 1):301-310; doi:10.18865/ed.31.S1.301

Introduction: Rectal prolapse constitutes in rectal protrusion through anal orifice. It’s more frequent in elderly women and the correction is exclusively surgical and fundamental, given the condition’s social relevance. We intend to describe a perineal rectosigmoidectomy (Altemeier) for correction of prolapse in multi-morbidity elder patient. Case Report: Female patient, 78 years old, evaluated by proctology ward of CHSBC. She Came in with complaint of anal region bulge for past 2 years. Proctological examination showed 15 cm rectal procidentia Rectal prolapse’s diagnosis came from colonoscopy. A perineal rectosigmoidectomy associated with colorectal anastomosis was done (Altemeier’s Procedure). There was appropriate postoperative evolution, discharge with good wound healing and ambulatorial follow up with good general healing. Discussion: Rectal prolapse is a result of anatomical alterations due to factors such as age and multiparity. Clinical presentation: abdominal discomfort, constipation, feces and gases release. It leads to life quality loss, thus surgical interventions become essential. Corrective surgeries seek to give back fecal continence. Currently, procedures branch out into abdominal and perineal. Altemeier consists in complete rectal removal via perineum. It’s appropriate for high surgical risk elders, since it has the lowest complications rate.

The goal of the paper is to explain the risk posed by rodent contaminated materials and environments to cultural heritage professionals, to provide sound information from professional literature and reputable sources, to offer standardized protocols gleaned from these sources, and to view the protocols through case studies from three projects. By spelling out the affinity that rodents have for historic sites, museum collections, archives holdings, records repositories, library collections, and cultural heritage infrastructure it will be clear the risk is paramount. By making clear the widespread habitat of rodents that can spread viruses the case is made for wide adoption of protocols. Diverse professionals, working in conservation and allied fields, can utilize information in this paper as a starting point in planning projects to assess, handle, and treat rodent impacted items, storage areas, and sites.

The cellular response to hypoxia is regulated through enzymatic oxygen sensors, including the prolyl hydroxylases, which control degradation of the well-known hypoxia inducible factors (HIFs). Other enzymatic oxygen sensors have been recently identified, including members of the KDM histone demethylase family. Little is known about how different oxygen-sensing pathways interact and if this varies depending on the form of hypoxia, such as chronic or intermittent. In this study, we investigated how two proposed cellular oxygen-sensing systems, HIF-1 and KDM4A, KDM4B, and KDM4C, respond in cells exposed to rapid forms of intermittent hypoxia (minutes) and compared to chronic hypoxia (hours). We found that intermittent hypoxia increases HIF-1α protein through a pathway distinct from chronic hypoxia, involving the KDM4A, KDM4B, and KDM4C histone lysine demethylases. Intermittent hypoxia increases the quantity and activity of KDM4A, KDM4B, and KDM4C, resulting in a decrease in histone 3 lysine 9 (H3K9) trimethylation near the HIF1A locus. We demonstrate that this contrasts with chronic hypoxia, which decreases KDM4A, KDM4B, and KDM4C activity, leading to hypertrimethylation of H3K9 globally and at the HIF1A locus. Altogether, we found that demethylation of histones bound to the HIF1A gene in intermittent hypoxia increases HIF1A mRNA expression, which has the downstream effect of increasing overall HIF-1 activity and expression of HIF target genes. This study highlights how multiple oxygen-sensing pathways can interact to regulate and fine tune the cellular hypoxic response depending on the period and length of hypoxia.

Background/aims Hypoxia Inducible Factor-1α (HIF-1α) is involved in cancer progression and is stabilized by the chaperone HSP90 (Heat Shock Protein 90), preventing degradation. Previously identified HSP90 inhibitors bind to the N-terminal pocket of HSP90, which blocks binding to HIF-1α and induces HIF-1α degradation. N-terminal inhibitors have failed in the clinic as single therapy treatments partially because they induce a heat shock response. SM molecules are HSP90 inhibitors that bind to the C-terminus of HSP90 and do not induce a heat shock response. The effects of these C-terminal inhibitors on HIF-1α are unreported. Methods HCT116, MDA-MB-231, PC3, and HEK293T cells were treated with HSP90 inhibitors. qRT-PCR and western blotting was performed to assess mRNA and protein levels of HIF-1α, HSP- and RACK1-related genes. siRNA was used to knockdown RACK1, while MG262 was used to inhibit proteasome activity. Dimethyloxalylglycine (DMOG) was used to inhibit activity of the prolyl hydroxylases (PHDs). Anti-angiogenic activity of HSP90 inhibitors was assessed using a HUVEC tubule formation assay. Results We show that SM compounds decrease HIF-1α target expression at the mRNA and protein level under hypoxia in colorectal, breast and prostate cancer cells, leading to cell death, without inducing a heat shock response. Surprisingly, we found that when the C-terminal of HSP90 is inhibited, HIF-1α degradation occurs through the proteasome and prolyl hydroxylases in an oxygen-dependent manner even in very low levels of oxygen (tumor hypoxia levels). RACK1 was not required for proteasomal degradation of HIF-1α. Conclusion Our results suggest that by targeting the C-terminus of HSP90 we can exploit the prolyl hydroxylase and proteasome pathway to induce HIF-1α degradation in hypoxic tumors.

Cellular oxygen-sensing pathways are primarily regulated by hypoxia inducible factor-1 (HIF-1) in chronic hypoxia and are well studied. Intermittent hypoxia also occurs in many pathological conditions, yet little is known about its biological effects. In this study, we investigated how two proposed cellular oxygen sensing systems, HIF-1 and KDM4A-C, respond to cells exposed to intermittent hypoxia and compared to chronic hypoxia. We found that intermittent hypoxia increases HIF-1 activity through a pathway distinct from chronic hypoxia, involving the KDM4A, -B and -C histone lysine demethylases. Intermittent hypoxia increases the quantity and activity of KDM4A-C resulting in a decrease in H3K9 methylation. This contrasts with chronic hypoxia, which decreases KDM4A-C activity, leading to hypermethylation of H3K9. Demethylation of histones bound to the HIF1A gene in intermittent hypoxia increases HIF1A mRNA expression, which has the downstream effect of increasing overall HIF-1 activity and expression of HIF target genes. This study highlights how multiple oxygen-sensing pathways can interact to regulate and fine tune the cellular hypoxic response depending on the period and length of hypoxia.

Racism is now widely recognized as a fundamental cause of health inequalities in the United States. As such, health scholars have rightly turned their attention toward examining the role of structural racism in fostering morbidity and mortality. However, to date, much of the empirical structural racism-health disparities literature limits the operationalization of structural racism to a single domain or orients the construct around a White/Black racial frame. This operationalization approach is incomprehensive and overlooks the heterogeneity of historical and lived experiences among other racial and ethnic groups. To address this gap, we present a theoretically grounded framework that illuminates core mutually reinforcing domains of structural racism that have stratified opportunities for health in the United States. We catalog instances of structural discrimination that were particularly constraining (or advantageous) to the health of racial and ethnic groups from the late 1400s to present. We then illustrate the utility of this framework by applying it to American Indians or Alaska Natives and discuss the framework’s broader implications for empirical health research. This framework should help future scholars across disciplines as they identify and interrogate important laws, policies, and norms that have differentially constrained opportunities for health among racial and ethnic groups.

The functional role of human derived stromal cells in the tumor microenviornment of CNS metastases (CM) remain understudied. The purpose of the current study was to isolate and characterize stromal cells of the tumor microenvironment in CM. Four different patient-derived cell lines (PDCs) of stromal and one PDC of tumorigenic origin were generated from breast or lung CM. PDCs were analyzed by DNA/RNA sequencing, DNA methylation profiling, and immunophenotypic assays. The stromal derived PDCs were termed CNS metastasis-associated stromal cells (cMASCs). Functional analysis of cMASCs was tested by co-implanting them with tumorigenic cells in mice. cMASCs displayed normal genotypes compared with tumorigenic cell lines. RNA-seq and DNA methylation analyses demonstrated that cMASCs highly resembled each other, suggesting a common cell of origin. Additionally, cMASCs revealed gene expression signatures associated with cancer associated fibroblasts (CAFs), epithelial to mesenchymal transition, mesenchymal stem cells and expressed high levels of collagen. Functionally, cMASCs restricted tumor growth, and induced desmoplasia in vivo, suggesting that cMASCs may promote a protective host response to impede tumor growth. In summary, we demonstrated the isolation, molecular characterization and functional role of human derived cMASCs, a subpopulation of cells in the microenvironment of CM that have tumor inhibitory functions.

Humans have internal circadian clocks that ensure that important physiological functions occur at specific times of the day. These molecular clocks are regulated at the genomic level and exist in most cells of the body. Multiple circadian resetting cues have been identified, including light, temperature, and food. Recently, oxygen has been identified as a resetting cue, and emerging science indicates that this occurs through interactions at the cellular level between the circadian transcription-translation feedback loop and the hypoxia-inducible pathway (hypoxia-inducible factor; subject of the 2019 Nobel Prize in Physiology or Medicine). This review will cover recently identified relationships between HIF and proteins of the circadian clock. Interactions between the circadian clock and hypoxia could have wide-reaching implications for human diseases, and understanding the molecular mechanisms regulating these overlapping pathways may open up new strategies for drug discovery.

Circadian rhythms regulate many physiological and behavioral processes, including sleep, metabolism and cell division, which have a 24-h oscillation pattern. Rhythmicity is generated by a transcriptional–translational feedback loop in individual cells, which are synchronized by the central pacemaker in the brain and external cues. Epidemiological and clinical studies indicate that disruption of these rhythms can increase both tumorigenesis and cancer progression. Environmental changes (shift work, jet lag, exposure to light at night), mutations in circadian regulating genes, and changes to clock gene expression are recognized forms of disruption and are associated with cancer risk and/or cancer progression. Experimental data in animals and cell cultures further supports the role of the cellular circadian clock in coordinating cell division and DNA repair, and disrupted cellular clocks accelerate cancer cell growth. This review will summarize studies linking circadian disruption to cancer biology and explore how such disruptions may be further altered by common characteristics of tumors including hypoxia and acidosis. We will highlight how circadian rhythms might be exploited for cancer drug development, including how delivery of current chemotherapies may be enhanced using chronotherapy. Understanding the role of circadian rhythms in carcinogenesis and tumor progression will enable us to better understand causes of cancer and how to treat them.

Despite recent advances in cancer therapy, options for central nervous system metastasis (CM) remain limited and patient outcomes are dismal. The lack of tumor models that reflect the heterogeneity and complexity of human CM tumors is a barrier to understanding the underlying biology and to developing novel therapies. Here, we report the development and characterization of 39 patient derived xenograft (PDX) models of CM tumors with histological subtypes representing the disease spectrum. The PDX models successfully grew both in the flank and brains of mice, and retained their histology regardless of the site of implantation. Brain metastasis also formed in 5/12 models after intra-cardiac injection. Multi-omic analysis of the PDX tumor and the patient-matched CM tumor showed that PDXs largely retained the molecular profiles of the tumor from which they were derived, including the retention of aberrations in key driver genes and signaling pathways. PDXs differed primarily from the ungrafted patient tumors by a downregulation in immunity-related pathways, which was expected due to the use of an immuno-compromised host, arguing for the validity of using the flank as a site of implantation. Integrated analysis of mutations and gene expression changes in CM revealed an upregulation of neuronal signaling and DNA damage response, and downregulation of calcium signaling and inflammation. We also assessed the clonal evolution of the PDX from the original patient CM by tracing variant allele frequencies in copy number neutral regions. We found that the PDX tumors were heterogeneous and comprised of multiple tumor clones that were either unique or in common with the original tumor, and displayed evidence of clonal expansion. Two PDXs that underwent phylogeny assessment showed evidence of minor clone expansion. One such PDX was a tumor from a Her2+ breast cancer (CM13), which largely did not molecularly resemble its matched patient tumor but was confirmed to have some shared expressed variants. The PDX was nearly copy number neutral, which included loss of the Her2 amplicon, and had few mutations compared with its parent tumor. Most noteworthy, is that CM13 displayed unique molecular patterns, aggressive growth and was highly metastatic in vivo. From the flank, it led to multiple metastases, including micrometastasis in the brain. This suggests that minor clone takeover may confer tumor aggressiveness and potentiate brain metastasis. The large and diverse repertoire of PDXs developed and characterized in this study provides a new set of tools that will help deepen our understanding of CM and improve preclinical testing for CM therapies. Our data also show that expansion of minor clones could confer aggressive tumor behavior and may be important in tumor evolution in PDX models and human cancers. Citation Format: Ben Yi Tew, Christophe Legendre, Tim Triche, Gerald C. Gooden, Kyle N. Johnson, Rae Anne Martinez, Emanuel F. Petricoin, Mariaelena Pierobon, Joyce O'Shaughnessy, Cindy Osborne, Mark A. Schroeder, Daniel J. Ma, Mark Bernstein, Jann N. Sarkaria, Steven A. Toms, Bodour Salhia. Development and characterization of patient derived xenografts from central nervous system metastasis reveal minor clone expansion linked with aggressive tumor behavior [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 991.

International audience; Microtubule drugs have been widely used in cancer chemotherapies. Although microtubules are subject to regulation by signal transduction mechanisms, their pharmacological modulation has so far relied on compounds that bind to the tubulin subunit. Using a cell-based assay designed to probe the microtubule polymerization status, we identified two pharmacophores, CM09 and CM10, as cell-permeable microtubule stabilizing agents. These synthetic compounds do not affect the assembly state of purified microtubules in vitro but they profoundly suppress microtubule dynamics in vivo. Moreover, they exert cytotoxic effects on several cancer cell lines including multidrug resistant cell lines. Therefore, these classes of compounds represent novel attractive leads for cancer chemotherapy.

Metastasis to the central nervous system (CNS) remains a major cause of mortality and morbidity in patients with systemic cancer. However, the mechanistic interactions of the neural niche with disseminated tumors cells in CNS metastases (CM) are still poorly understood. To better understand the cross-talk between the neural niche and metastatic tumors, we generated five different patient-derived cell lines (PDCs) originating from surgically resected CM. To assess the genetic and epigenetic characteristics of each PDC, DNA and RNA sequencing, and DNA methylation analysis was performed. Non-tumoral PDCs revealed normal copy number profiles, and retention of germline mutations as seen in patient-matched germline DNA. In contrast, one PDC (CM04) resembled its patient tumor, showing numerous copy number and somatic alterations. RNA-seq and DNA methylation analysis demonstrated that non-tumoral PDCs highly resembled each other, suggestive of a common cell of origin. Additionally, PDCs revealed gene expression signatures associated with cancer associated fibroblasts, epithelial to mesenchymal transition, and mesenchymal stem cells. Further in vivo studies demonstrated that CM04 cells were tumorigenic, whereas non-tumoral PDC (CM08) cells were unable to form tumors in mice. However, CM04:CM08 mixed tumors were significantly smaller than CM04 only tumors and revealed induction of a fibrotic response by immunohistochemistry. These data offer the first evidence that CNS metastasis-associated stromal cells (cMASCs) produce a collagen and fibronectin-rich extracellular matrix constituting a protective host response, which impedes growth of tumor cells. The therapeutic potential of these cells merits further exploration. Citation Format: Christophe Legendre, Gerald C. Gooden, Kyle N. Johnson, Rae Anne Martinez, Mark Bernstein, Jennifer Glen, Jeffrey Kiefer, Aleksander Hinek, Steven A. Toms, Bodour Salhia. Human mesodermal-derived CNS metastasis-associated stromal cells induce a fibrotic response to limit tumor growth [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 4336. doi:10.1158/1538-7445.AM2017-4336

Background and Purpose Drugs targeting microtubules are commonly used for cancer treatment. However, the potency of microtubule inhibitors used clinically is limited by the emergence of resistance. We thus designed a strategy to find new cell-permeable microtubule-targeting agents. Experimental Approach Using a cell-based assay designed to probe for microtubule polymerization status, we screened a chemical library and identified two azaindole derivatives, CM01 and CM02, as cell-permeable microtubule-depolymerizing agents. The mechanism of the anti-tumour effects of these two compounds was further investigated both in vivo and in vitro. Key Results CM01 and CM02 induced G2/M cell cycle arrest and exerted potent cytostatic effects on several cancer cell lines including multidrug-resistant (MDR) cell lines. In vitro experiments revealed that the azaindole derivatives inhibited tubulin polymerization and competed with colchicines for this effect, strongly indicating that tubulin is the cellular target of these azaindole derivatives. In vivo experiments, using a chicken chorioallantoic xenograft tumour assay, established that these compounds exert a potent anti-tumour effect. Furthermore, an assay probing the growth of vessels out of endothelial cell spheroids showed that CM01 and CM02 exert anti-angiogenic activities. Conclusions and Implications CM01 and CM02 are reversible microtubule-depolymerizing agents that exert potent cytostatic effects on human cancer cells of diverse origins, including MDR cells. They were also shown to inhibit angiogenesis and tumour growth in chorioallantoic breast cancer xenografts. Hence, these azaindole derivatives are attractive candidates for further preclinical investigations.

Background A number of clinico-pathological criteria and molecular profiles have been used to stratify patients into high- and low-risk groups. Currently, there are still no effective methods to determine which patients harbor micrometastatic disease after standard breast cancer therapy and who will eventually develop local or distant recurrence. The purpose of our study was to identify circulating DNA methylation changes that can be used for prediction of metastatic breast cancer (MBC). Results Differential methylation analysis revealed ~5.0 × 106 differentially methylated CpG loci in MBC compared with healthy individuals (H) or disease-free survivors (DFS). In contrast, there was a strong degree of similarity between H and DFS. Overall, MBC demonstrated global hypomethylation and focal CpG island (CPGI) hypermethylation. Data analysis identified 21 novel hotspots, within CpG islands, that differed most dramatically in MBC compared with H or DFS. Conclusions This unbiased analysis of cell-free (cf) DNA identified 21 DNA hypermethylation hotspots associated with MBC and demonstrated the ability to distinguish tumor-specific changes from normal-derived signals at the whole-genome level. This signature is a potential blood-based biomarker that could be advantageous at the time of surgery and/or after the completion of chemotherapy to indicate patients with micrometastatic disease who are at a high risk of recurrence and who could benefit from additional therapy. Electronic supplementary material The online version of this article (doi:10.1186/s13148-015-0135-8) contains supplementary material, which is available to authorized users.

Although several improvements in the management of breast cancer(BC) have been made, an estimated 90% of BC related deaths are due to the development of distant metastasis to organs such as lung, bone, liver, and brain. Numerous studies suggest that cell-free (cf)DNA methylation could serve as a useful biomarker for improving clinical management. The objective of our study was to identify novel blood-based biomarkers that can be used to predict BC patients at high risk of distant metastasis. For the first time we performed paired-end whole genome bisulfite sequencing (WGBS) using 15 ng of cf plasma DNA from three pools of samples which included metastatic BC to various organs (M, n = 40), breast cancer free survivors (BCF n = 40) and healthy individuals (H, n = 40). Sequences were aligned using the bismark tool and data analysis was conducted using the R package methylKit to identify base-pair resolution DNA methylation differences between groups. A minimum of 5 reads in each group, delta beta values ≥0.2 and p values Citation Format: Christophe Legendre, Gerald C. Gooden, Kyle N. Johnson, Rae Anne Martinez, Bodour Salhia. Whole genome bisulfite sequencing from plasma of patients with metastatic breast cancer identifies putative biomarkers. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 3825. doi:10.1158/1538-7445.AM2015-3825

2-Methoxyestradiol (2ME2) is a naturally occurring estradiol metabolite which possesses antiproliferative, antiangiogenic and antitumor properties. However, due to its limited biological accessibility, synthetic analogues have been synthesized and tested in attempt to develop drugs with improved oral bioavailability and efficacy. The aim of this study was to evaluate the antiproliferative effects of three novel in silico-designed sulphamoylated 2ME2 analogues on the HeLa cervical adenocarcinoma cell line and estrogen receptor-negative breast adenocarcinoma MDA-MB-231 cells. A dose-dependent study (0.1–25 μM) was conducted with an exposure time of 24 hours. Results obtained from crystal violet staining indicated that 0.5 μM of all 3 compounds reduced the number of cells to 50%. Lactate dehydrogenase assay was used to assess cytotoxicity, while the mitotracker mitochondrial assay and caspase-6 and -8 activity assays were used to investigate the possible occurrence of apoptosis. Tubulin polymerization assays were conducted to evaluate the influence of these sulphamoylated 2ME2 analogues on tubulin dynamics. Double immunofluorescence microscopy using labeled antibodies specific to tyrosinate and detyrosinated tubulin was conducted to assess the effect of the 2ME2 analogues on tubulin dynamics. An insignificant increase in the level of lactate dehydrogenase release was observed in the compounds-treated cells. These sulphamoylated compounds caused a reduction in mitochondrial membrane potential, cytochrome c release and caspase 3 activation indicating apoptosis induction by means of the intrinsic pathway in HeLa and MDA-MB-231 cells. Microtubule depolymerization was observed after exposure to these three sulphamoylated analogues.

Drugs targeting microtubules are commonly used for cancer treatment. However, the potency of microtubule inhibitors used clinically is limited by the emergence of resistance. We thus designed a strategy to find new cell-permeable microtubule-targeting agents.Using a cell-based assay designed to probe for microtubule polymerization status, we screened a chemical library and identified two azaindole derivatives, CM01 and CM02, as cell-permeable microtubule-depolymerizing agents. The mechanism of the anti-tumour effects of these two compounds was further investigated both in vivo and in vitro.CM01 and CM02 induced G2/M cell cycle arrest and exerted potent cytostatic effects on several cancer cell lines including multidrug-resistant (MDR) cell lines. In vitro experiments revealed that the azaindole derivatives inhibited tubulin polymerization and competed with colchicines for this effect, strongly indicating that tubulin is the cellular target of these azaindole derivatives. In vivo experiments, using a chicken chorioallantoic xenograft tumour assay, established that these compounds exert a potent anti-tumour effect. Furthermore, an assay probing the growth of vessels out of endothelial cell spheroids showed that CM01 and CM02 exert anti-angiogenic activities.CM01 and CM02 are reversible microtubule-depolymerizing agents that exert potent cytostatic effects on human cancer cells of diverse origins, including MDR cells. They were also shown to inhibit angiogenesis and tumour growth in chorioallantoic breast cancer xenografts. Hence, these azaindole derivatives are attractive candidates for further preclinical investigations.

The emergence of tumor resistance to conventional microtubule-targeting drugs restricts their clinical use. Using a cell-based assay that recognizes microtubule polymerization status to screen for chemicals that interact with regulators of microtubule dynamics, we identified Pyr1, a cell permeable inhibitor of LIM kinase, which is the enzyme that phosphorylates and inactivates the actin-depolymerizing factor cofilin. Pyr1 reversibly stabilized microtubules, blocked actin microfilament dynamics, inhibited cell motility in vitro and showed anticancer properties in vivo, in the absence of major side effects. Pyr1 inhibition of LIM kinase caused a microtubule-stabilizing effect, which was independent of any direct effects on the actin cytoskeleton. In addition, Pyr1 retained its activity in multidrug-resistant cancer cells that were resistant to conventional microtubule-targeting agents. Our findings suggest that LIM kinase functions as a signaling node that controls both actin and microtubule dynamics. LIM kinase may therefore represent a targetable enzyme for cancer treatment. Cancer Res; 72(17); 4429–39. ©2012 AACR.