ACS Medicinal Chemistry Letters Research Articles

Toward the elucidation of the mechanism for passive membrane permeability of cyclic peptides.

Toward the elucidation of the mechanism for passive membrane permeability of cyclic peptides.

Antimicrobial 2-aminothiazolyl quinolones: what is their potential in the clinic?

Antimicrobial 2-aminothiazolyl quinolones: what is their potential in the clinic?

Retraction of "novel 2-aminobenzamides as potential orally active antithrombotic agents".

[This retracts the article DOI: 10.1021/ml300217f.].

Call for Papers! A Special Thematic Compilation/Special Issue Crossover with ACS Chemical Biology, ACS Medicinal Chemistry Letters, and the Journal of Medicinal Chemistry Focused on New Frontiers in Kinases

Call for Papers! A Special Thematic Compilation/Special Issue Crossover with <i>ACS Chemical Biology, ACS Medicinal Chemistry Letters</i>, and the <i>Journal of Medicinal Chemistry</i> Focused on New Frontiers in Kinases

ACS Chemical Neuroscience and Neuroscience Drug Discovery as 2012 Comes to a Close

Well, 2012 is almost over—hard to believe. ACS Chemical Neuroscience has now been publishing high quality neuroscience research for three years! The year 2012 presented several major milestones for ACS Chemical Neuroscience: we received our first impact factor (3.676) based on 2011 metrics, and we expanded our Associate Editors to include Dr. Anne Andrews (UCLA). In addition, both the number of manuscripts submitted to ACS Chemical Neuroscience and the number of citations to ACS Chemical Neuroscience manuscripts (Web of Science) has dramatically increased in 2012. In 2012, we also had our first thematic crossover issue with the Journal of Medicinal Chemistry and ACS Medicinal Chemistry Letters on Alzheimer’s disease (AD).1 From myself, the Associate Editors, and all at ACS, we want to extend a heartfelt thank you to all of the contributing authors to ACS Chemical Neuroscience since our launch in 2010, and for making ACS Chemical Neuroscience a desirable venue to publish your best neuroscience research. As for neuroscience drug discovery, 2012 witnessed a number of low points, with multiple companies pulling out of neuroscience drug discovery and a long list of phase II failures of CNS therapeutics (both small molecules and biologics), and in particular for AD1 and schizophrenia. Of these, the disappointing news that the Lilly mGlu2/3 agonist, Pomaglutamed Methionil, was unlikely to be positive in its primary end points in a phase III schizophrenia trial, that led the company to halt development.2 This is especially sad news, as the positive phase II data energized the industry with success of a nondopaminergic, novel mechanism for schizophrenic patients. However, as 2012 draws to a close, two bright lights have appeared. Janssen Pharmaceuticals and Addex Therapeutics announced that {type:entrez-protein,attrs:{text:ADX71149,term_id:323467462,term_text:ADX71149}}ADX71149, an mGlu2 positive allosteric modulator (PAM), demonstrated safety and tolerability as well as top-line data from a phase IIa monotherapy study in schizophrenic patients.3 A phase IIb trial is underway to explore the potential of the mGlu2 PAM as an adjunctive therapy with standard antipsychotics. Will the PAM succeed where the agonist failed? Speculation on neuroscience blogs suggests the agonist, with chronic dosing, may have desensitized the receptor. It will be most interesting to follow {type:entrez-protein,attrs:{text:ADX71149,term_id:323467462,term_text:ADX71149}}ADX71149 as it progresses through development to test the PAM mechanism, the target (mGlu2) and to offer a new therapeutic alternative to schizophrenic patients. Addex Therapeutics’ Dipraglurant, an mGlu5 negative allosteric modulator (NAM), was just named one of the “Top 10 Neuroscience Projects” to watch by Windhover and Virginia Herndon. Dipraglurant is an oral mGlu5 NAM that has demonstrated both safety and tolerability as well as efficacy in Parkinsons patients with leva-DOPA-induced diskinesias (LID).3 Efficacy was observed at both 50 and 100 mg doses. Moreover, Dipraglurant reduced dystonia severity and chorea, the two major components of LID. Overall, this is very exciting data for the approach of allosteric modulation of GPCRs and for patients suffering from LID; phase III data is eagerly awaited. In 2013, we plan to continue Viewpoint features on CNS therapeutics and solicit ideas and Viewpoints from the community. Again, we want ACS Chemical Neuroscience to also serve as a forum for scientific exchange on neuroscience and encourage your participation. We have a number of exciting things planned for 2013—visit the ACS Chemical Neuroscience Web site often for updates.

Alzheimer’s Disease: Development of Disease-Modifying Treatments Is the Challenge for Our Generation

Welcome to our first thematic collection that crosses-over with the Journal of Medicinal Chemistry and ACS Medicinal Chemistry Letters to highlight advances in the pharmacology, medicinal chemistry, and therapeutic strategies currently under development for Alzheimer’s disease (AD)—the most challenging and important disease facing our generation. While the 1970s heralded a “war on cancer” and the 1980s and 1990s witnessed a monumental effort to vanquish the death sentence of AIDs with novel therapeutics targeting multiple aspects of the viral machinery, the challenge of this millennium is the development of disease-modifying treatments for AD. Unfortunately, even after several decades of research, there are few approved drugs for AD; moreover, the available drugs only attenuate symptoms, show little to no effect on slowing disease progression, and have no effect on the behavioral disturbances associated with AD.1−4 Current estimates indicate that approximately 5.4 million Americans are suffering from AD at an annual cost to the United States healthcare system of over $200 billion.1−4 While staggering, the situation grows more desperate as the 76 million baby boomers advance in age. This is based on the likelihood of developing AD doubles every 5 years after age 65, and after age 85 the risk of developing AD climbs to ∼50%. Importantly, if no disease-modifying therapies are developed, the number of AD patients may climb as high as 13.5 million by 2050, resulting in over $1 trillion in patient care costs.1−4 An even more sobering statistic focuses on mortality and AD. Between 2000 and 2008, there was a 66% increase in deaths directly related to AD; in contrast, during the same time period, deaths from HIV decreased 29%, deaths from stroke decreased 20%, deaths from heart disease decreased 13%, and deaths from several cancers also declined significantly.1−4 Early neuropathology of AD is characterized by the loss of basal forebrain cholinergic neurons and loss of cholinergic neurotransmission. Current approved drugs for AD target cholinergic and glutamatergic transmission thereby improving cognitive symptoms in some patients; however, these agents are not disease-modifying, nor do they slow disease progression. Current approved therapies include cholinesterase inhibitors (tacrine (Cognex), donepezil (Aricept), rivastigmine (Exelon), and galanatamine (Razadyne)) and the glutamate modulator memantine (Namenda).1−4 The other major hallmarks of AD include plaques and neurofibrillary tangles in the brain which led to the amyloid hypothesis and tau hypothesis in 1991 and 2004, respectively, as fundamental causes of AD. Drug development efforts have pursued these hypotheses via multiple approaches.1−4 The amyloid hypothesis of AD initiated major drug discovery efforts across the pharmaceutical industry, with novel small molecules targeting Aβ peptide production. Aβ is produced by the proteolytic cleavage of APP by γ- and β-secretases leading to Aβ1–40 and Aβ1–42 peptides which aggregate and form toxic oligomers.1−4 The amyloid hypothesis has undergone many revisions and refinements since 1991, and with multiple failures of both small molecules and biologic approaches that diminish Aβ load, there is growing debate that targeting Aβ may be questionable as an AD therapeutic approach.1−5 However, others argue that the hypothesis is still valid and that the issues were with inferior molecules, biologics, the “sink” approach and/or trial design. Numerous BACE1 inhibitors are in phase I trials, where compounds such as MK-8931, lowered Aβ up to 90%, and efficacy in phase II are eagerly awaited.6 PhRMA reports in their 2012 Medicines in Development Report for AD4 that there are currently 93 medicines in various stages of development, both small molecule and biologic. In general, all 93 compounds fall into one of the following therapeutic strategies: (1) agents targeting neurotransmission, (2) agents targeting Aβ production, (3) agents targeting Aβ aggregation, (4) agents targeting Aβ clearance, (5) agents increasing brain resistance to Aβ, (6) agents targeting tau protein, and (7) agents targeting neurotrophins and agents modulating synaptic plasticity and nerve growth.1−4 Significant advances have been, and continue to be made, in the development of imaging agents, for example, Amyvid,1−4 for amyloid imaging biomarkers for disease. Overall, new therapeutic agents must address multiple stages of disease progression, from Aβ/tau accumulation to mild cognitive impairment to late stage dementia and behavioral (psychotic) symptoms, the latter of which are more difficult for caregivers than the dementia. In this Special Issue on AD, we present 17 outstanding papers (both reviews and primary scientific studies) encompassing basic neuropathology, novel therapeutic strategies, novel small molecules, and genetic studies relevant to understanding and treating AD. We at ACS Chemical Neuroscience thank all of the contributors to this special issue on AD and encourage our readers to take advantage of our first thematic collection that crosses-over with the Journal of Medicinal Chemistry and ACS Medicinal Chemistry Letters and check out the outstanding papers in these Journals on AD.

Call for Papers! A Special Thematic Compilation/Special Issue Crossover with the Journal of Medicinal Chemistry and ACS Medicinal Chemistry Letters Focused on Alzheimer’s Disease

Call for papers! ACS Chemical Neuroscience is sending out a broad call for manuscripts (reviews, letters, articles, and viewpoints) for a special issue focused on all aspects of Alzheimer’s disease. The upcoming special issue will be the first cross thematic issue between the Journal of Medicinal Chemistry, ACS Medicinal Chemistry Letters, and ACS Chemical Neuroscience, with a focus on the pharmacology, medicinal chemistry, and biology of the most challenging and important disease facing our generation—Alzheimer’s disease (AD). According to the Alzheimer’s Association,1 over 5.4 million Americans have AD, and the majority of these cases (5.2 million) are in individuals over the age of 65. Importantly, one in eight people over 65 (13%) have AD, and that percentage increases to 43% in people over 85. Interestingly, 66% (3.4 million) of Americans with AD are women. With the aging baby boomers, AD will impact our society and the world in terms of people afflicted and the burden of care for AD patients.1 For this cross thematic, ACS Chemical Neuroscience will publish manuscripts that showcase the latest chemical, quantitative biological, biophysical, and bioengineering approaches for both symptomatic and disease modifying tactics—destined to be a must read for anyone working in the AD field. The Editors welcome preclinical as well as clinical studies with novel agents/targets. Manuscripts in ACS Chemical Neuroscience will be cross-referenced with the manuscripts in the Journal of Medicinal Chemistry and ACS Medicinal Chemistry Letters, and will garner high exposure via a number of ACS marketing initiatives. We are tentatively aiming for publication in the November 2012 issue; therefore, all submissions for this Special issue must be received no later than July of 2012 for inclusion. Feel free to e-mail me directly with inquiries and/or to propose content. There will be a special issue option in Paragon Plus for manuscripts for this special issue of ACS Chemical Neuroscience. I invite you to be a part of ACS history for our first trijournal crossover and to contribute to the field’s knowledge on AD as we advance toward a cure.

ACS Chemical Neuroscience in 2012: Opportunities and Challenges

Year three of publication of ACS Chemical Neuroscience is upon us—how quickly time flies. Once again, I would like to thank the Associate Editors, Arthur Christopoulos (Monash University) and Alan Jasanoff (MIT), for all of their hard work and volume of manuscripts handled last year—we saw a large increase in submissions. As always, ACS editorial staff have been amazing, and marketing for ACS Chemical Neuroscience has been present at most major neuroscience meetings. Moving into year three, the Journal welcomes Anne M. Andrews (UCLA) as a new Associate Editor, bringing complementary expertise in neuroscience to the editorial board—welcome Anne! We also anticipate three Special Issues in 2012 with Associate Editors Arthur Christopoulos (Monash University) and Alan Jasanoff (MIT), and Benjamin Cravat (SCRIPPS) serving as Guest Editors for their respective Special Issues. We are also planning a thematic crossover with both ACS Medicinal Chemistry Letters and the Journal of Medicinal Chemistry—more on this next month. Moreover, ACS Chemical Neuroscience wants to extend a warm welcome to the new Editors-in-Chief of the Journal of Medicinal Chemistry, Shaomeng Wang and Gunda Georg, and a fond farewell and deep thanks to Philip Portoghese, who made JMC the best medicinal chemistry journal in the world and paved the way for the biological journals within the ACS. Finally, during year three of the Journal, we will learn of the initial Impact Factor. While we can only speculate, based on citations (an ∼7-fold increase in citations in 2011 over 2010), h-index (ACS Chemical Neuroscience has an h-index of 8), and other parameters, we are expecting an impressive Impact Factor for the first neuroscience journal in the American Chemical Society Publications family. 2011 has been a year of major challenges for CNS research, with several major pharmaceutical companies announcing they were leaving altogether and/or significantly downsizing CNS drug discovery. Fortunately, academic drug discovery groups are emerging with CNS focus, and NIH has developed new RFAs to fund drug discovery as well as the highly successful Molecular Libraries Probe Production Center Network (MLPCN). However, lower pay-lines for grant funding continue to put a strain on academics and slow neuroscience research. Importantly, many foundations fund neuroscience research, and many have focused drug discovery funding opportunities—all of these can be found on the ACS Chemical Neuroscience Web site. A huge development at the end of 2011 was the announcement that Congress will fund the National Center for Advancing Translational Sciences (NCATS), and the existing network of Clinical Translational Science Awards (CTSAs) will be brought into NCATS. Hopefully, this will foster new avenues for CNS drug discovery in the academic sector, with full translation into clinical studies. Both the MLPCN and NCATS are necessary to continue innovation in CNS research and therapeutics development in light of the departure of big pharma. In closing, there is a special session entitled Chemical Neuroscience within the Organic Division at the 2012 Spring ACS Meeting in San Diego. The Session features authors and Editors of ACS Chemical Neuroscience and other notable neuroscientists. Please stop by for the session and visit the ACS Chemical Neuroscience booth. 2012 promises to be an important and pivotal year for chemical neuroscience, CNS drug discovery, and ACS Chemical Neuroscience.

Research Highlights

Research Highlights

The Global Sepsis Alliance: Building New Collaborations to Confront an Under-Recognized Threat

Surgical InfectionsVol. 12, No. 1 EditorialThe Global Sepsis Alliance: Building New Collaborations to Confront an Under-Recognized ThreatJohn C. Marshall and Konrad ReinhartJohn C. MarshallSearch for more papers by this author and Konrad ReinhartSearch for more papers by this authorPublished Online:10 Feb 2011https://doi.org/10.1089/sur.2010.9923AboutSectionsView articleView Full TextPDF/EPUB ToolsPermissionsDownload CitationsTrack CitationsAdd to favorites Back To Publication ShareShare onFacebookTwitterLinked InRedditEmail View articleAbstractFiguresReferencesRelatedDetailsCited ByCharacteristics of bacterial sepsis among patients with visceral leishmaniasisAsian Pacific Journal of Tropical Biomedicine, Vol. 4, No. 11Synthesis and Anti-inflammatory Evaluation of Novel Benzimidazole and Imidazopyridine Derivatives5 December 2012 | ACS Medicinal Chemistry Letters, Vol. 4, No. 1World Sepsis Day: September 13, 2012 Philip S. Barie7 September 2012 | Surgical Infections, Vol. 13, No. 4Nurses’ Critical Role in Identifying Sepsis and Implementing Early Goal-Directed TherapyThe Journal of Continuing Education in Nursing, Vol. 43, No. 6 Volume 12Issue 1Feb 2011 InformationCopyright 2011, Mary Ann Liebert, Inc.To cite this article:John C. Marshall and Konrad Reinhart.The Global Sepsis Alliance: Building New Collaborations to Confront an Under-Recognized Threat.Surgical Infections.Feb 2011.1-2.http://doi.org/10.1089/sur.2010.9923Published in Volume: 12 Issue 1: February 10, 2011PDF download

Introductory Editorial for ACS Medicinal Chemistry Letters.

“May you live in interesting times.” This English translation of an ancient Chinese proverb (and curse) seems well-suited to describe the current state of medicinal chemistry. In the pharmaceutical industry, the mergers and acquisitions of the past decade have forced an increasing number of medicinal chemists to find nontraditional ways to ply their trade. Over the same time period, academia has seen a steady growth in the number of scientists who use “medicinal chemistry” as one of their descriptors. Indeed, medicinal chemistry has broadened in terms of interfacial fields of study, such as chemical biology, chemical physiology, proteomics, and metabolomics, which add richness to its intellectual content. Layer on top of this the huge technical advances that have occurred in this field, as well as in the many biological and computational fields that directly impinge on it, and you'll understand why “interesting times” concisely conveys the dynamism of this rapidly evolving area of study. So how can practicing medicinal chemists keep up with all of the innovations and changes that are happening in the field? I suggest that that one of the best ways is for you to become a regular reader of ACS Medicinal Chemistry Letters, a new journal that is as fast-paced as the field that it serves. As its founding Editor-in-Chief, I am fully committed to making it the premier international journal for rapid communication of cutting-edge studies that span all areas of medicinal chemistry. ACS Medicinal Chemistry Letters will keep you at the forefront of the field with quick, brief reports of experimental and theoretical results in all aspects of medicinal chemistry (pure and applied) and its extension into pharmacology. The journal publishes high-quality studies on subjects ranging from compound discovery, design, and optimization; biological evaluation and new screening methodology; drug metabolism and delivery; new targets and their ligands; and molecular pharmacology. In addition, ACS Medicinal Chemistry Letters welcomes articles that describe innovations to the “Drug Discovery Toolbox”, the basket term that we use to describe a myriad of technologies, such as high-throughput/high-content screening, robotics, structure-based drug design, fragment-based drug design, combinatorial chemistry/parallel synthesis, etc., which simultaneously facilitate and partially define modern medicinal chemistry. In the coming months ACS Medicinal Chemistry Letters will also initiate a section dealing with “hot” patents, that is, recently issued medicinal chemistry patents, which may be at the time of issue the only public domain source of scientific details in the selected areas. The coverage would feature patents and published patent applications in high-interest areas with brief commentaries on their potential impact. Medicinal chemistry research can (and often does) change the world for the benefit of mankind. However, to the public and even to many of our biomedical colleagues, our field is increasingly being viewed as a support service for the biological sciences, rather than as one of the fundamental components of drug discovery and development. I believe that it is time to re-educate these groups about the importance of medicinal chemistry and about the constant stream of innovations that is being developed in this area. As a consequence, ACS Medicinal Chemistry Letters will from time to time include editorials from the Editor(s) or OpEd (Viewpoint) articles from invited guests that discuss specific issues and innovations in medicinal chemistry or general issues involving pharmaceutical development. We will welcome opposing viewpoints or responses to OpEd pieces to facilitate a dialogue with the community. We have put together a great editorial team that includes Dr. Bruce Maryanoff, now at The Scripps Research Institute in La Jolla, and Dr. Peter Wipf at the University of Pittsburgh, and me. Together, we have crafted a set of criteria for compound characterization and Supporting Information that is rigorous but at the same time neither time-consuming nor onerous. We are trying to be sensitive to the needs of the scientific community by limiting unnecessary administrative burdens to the publication of quality work. As a plus for prospective authors, our online format permits Letters to be up to 5 pages in size. We expect to publish articles within 4−6 weeks of submission, and our award-winning ACS Publications Web Editions Platform will showcase your important findings to the international scientific community. I invite you to submit your late-breaking research to ACS Medicinal Chemistry Letters. Backed by the full support of the American Chemical Society, we will deliver the most urgent research results to the world in record time.

Hunting for the SNARK in metabolic disease

dysregulation of energy balance is a primary constituent in the etiology of obesity and type 2 diabetes mellitus, which is manifested by altered metabolic homeostasis and insulin resistance in a variety of tissues, including brain, liver, and skeletal muscle. The discovery of the AMP-activated

A New Kid on the Block

The formation of blood vessels through the process of angiogenesis is critical in normal vascular development and numerous vascular disorders. The most prominent stimulus for angiogenic processes in endothelial cells is vascular endothelial growth factor (VEGF), which regulates their migration, proliferation, and survival.1 The crucial role for this factor is documented by the lethal phenotype resulting from disruption of a single allele in mice.2,3 Binding of VEGF to its receptors activates several intracellular signaling molecules, among them phospholipase Cγ (PLCγ), protein kinase C (PKC), protein kinase D (PKD), and phosphatidyl-insitol-3 kinase (PI3K).1 The VEF-induced signaling events finally culminate in gene expression changes in the nucleus. See accompanying article on page 1782 A key regulator of gene expression is chromatin structure, which is largely determined by the acetylation status of histones. In general, acetylation of these nucleosomal proteins by histone acetyl transferases (HATs) stimulates transcription, whereas deacetylation by histone deacetylases (HDACs) leads to transcriptional repression. The HDAC family comprises 18 members in humans, which are classified based on their homologies to yeast proteins. …

Prevention of acute mountain sickness by acetazolamide: as yet an unfinished story

since the 1970s, over 200 studies with acetazolamide have shown it safe and 60–80% effective in acute mountain sickness (AMS). Despite much investigation, our understanding of its action in AMS remains incomplete and more complicated than generally taught. This should come as no surprise