Open questions for harnessing autophagy-modulating drugs in the SARS-CoV-2 war: hope or hype?

At a time when the world faces an emotional breakdown, crushing our dreams, if not, taking our lives, we realize that together we must fight the war against the COVID-19 outbreak even if almost the majority of the scientific community finds itself confined at home. Every day, we, scientists, listen to the latest news with its promises and announcements. Across the world, a surge of clinical trials trying to cure or slow down the coronavirus pandemic has been launched to bring hope instead of fear and despair. One first proposed clinical trial has drawn worldwide hype to the benefit of chloroquine (CQ), in the treatment of patients infected by the recently emerged deadly coronavirus (SARS-CoV-2). We should consider this information in light of the long-standing anti-inflammatory and anti-viral properties of CQ-related drugs. Yet, none of the articles promoting the use of CQ in the current pandemic evoked a possible molecular or cellular mechanism of action that could account for any efficacy. Here, given the interaction of viruses with macroautophagy (hereafter referred to as autophagy), a CQ-sensitive anti-viral safeguard pathway, we would like to discuss the pros, but also the cons concerning the current therapeutic options targeting this process.

Screening Marine Natural Products for New Drug Leads against Trypanosomatids and Malaria.

Neglected Tropical Diseases (NTD) represent a serious threat to humans, especially for those living in poor or developing countries. Almost one-sixth of the world population is at risk of suffering from these diseases and many thousands die because of NTDs, to which we should add the sanitary, labor and social issues that hinder the economic development of these countries. Protozoan-borne diseases are responsible for more than one million deaths every year. Visceral leishmaniasis, Chagas disease or sleeping sickness are among the most lethal NTDs. Despite not being considered an NTD by the World Health Organization (WHO), malaria must be added to this sinister group. Malaria, caused by the apicomplexan parasite Plasmodium falciparum, is responsible for thousands of deaths each year. The treatment of this disease has been losing effectiveness year after year. Many of the medicines currently in use are obsolete due to their gradual loss of efficacy, their intrinsic toxicity and the emergence of drug resistance or a lack of adherence to treatment. Therefore, there is an urgent and global need for new drugs. Despite this, the scant interest shown by most of the stakeholders involved in the pharmaceutical industry makes our present therapeutic arsenal scarce, and until recently, the search for new drugs has not been seriously addressed. The sources of new drugs for these and other pathologies include natural products, synthetic molecules or repurposing drugs. The most frequent sources of natural products are microorganisms, e.g., bacteria, fungi, yeasts, algae and plants, which are able to synthesize many drugs that are currently in use (e.g. antimicrobials, antitumor, immunosuppressants, etc.). The marine environment is another well-established source of bioactive natural products, with recent applications against parasites, bacteria and other pathogens which affect humans and animals. Drug discovery techniques have rapidly advanced since the beginning of the millennium. The combination of novel techniques that include the genetic modification of pathogens, bioimaging and robotics has given rise to the standardization of High-Performance Screening platforms in the discovery of drugs. These advancements have accelerated the discovery of new chemical entities with antiparasitic effects. This review presents critical updates regarding the use of High-Throughput Screening (HTS) in the discovery of drugs for NTDs transmitted by protozoa, including malaria, and its application in the discovery of new drugs of marine origin.

Towards histone deacetylase inhibitors as new antimalarial drugs.

Histone deacetylases (HDACs) are important enzymes that effect post-translational modifications of proteins by altering the acetylation state of lysine residues. HDACs control epigenetic changes that trigger cell transformation and proliferation of transformed cells associated with many diseases. These enzymes are validated drug targets for some types of cancer and are promising therapeutic targets for a range of other diseases, including malaria. Annually, there are ~500 million clinical cases of malaria and ~0.8-1.2 million deaths. There is no licensed vaccine for preventing malaria, and parasites that cause malaria are becoming resistant to current drugs, necessitating the search for new therapies. HDAC inhibitors are emerging as a promising new class of antimalarial drugs with potent and selective action against Plasmodium parasites in vitro. Recent studies on the effects of HDAC inhibitors on the growth and development of P. falciparum have provided important new information on transcriptional regulation in malaria parasites and have validated the potential of this class of inhibitors for malaria therapy. To realise effective HDAC inhibitors for clinical trials, next generation inhibitors must not inhibit other human HDACs or proteins required for normal human physiology, be highly selective in killing parasites in vivo without killing normal host cells, and have improved bioavailability and pharmacokinetic profiles. This review summarizes current knowledge about malaria parasite HDACs and HDAC inhibitors with antimalarial properties, and provides insights for their development into new drugs for treatment of malaria.

Estrogen and progesterone affect responses to malaria infection in female C57BL/6 mice.

BACKGROUND: Previous data from our laboratory suggest that gonadally intact C57BL/6 male mice are more likely than their female counterparts to die from Plasmodium chabaudi infection, to recover more slowly from weight loss and hematocrit loss, and to have reduced interferon-gamma (IFN-gamma) and interleukin-10 (IL-10) responses. Removal of the ovaries, and hence, the primary production of sex steroids in females, reverses these differences. OBJECTIVE: We hypothesized that sex differences in response to P chabaudi may be mediated by differential synthesis of IFN-gamma and IL-10 that is influenced by estrogen, progesterone, or both. METHODS: C57BL/6 female mice (n = 200; n = 10/time point/treatment/experiment) were ovariectomized and implanted with a 21-day controlled-release pellet containing either 0.1 mg of 17beta-estradiol (E(2)), 10 mg of progesterone (P(4)), 0.1 mg of E(2) plus 10 mg of P(4), or cholesterol (placebo). Females were inoculated with 10(6)P chabaudi-infected erythrocytes. Body mass, body temperature, hematocrit, parasitemia, cytokine production, and antibody responses were monitored 0, 3, 5, 7, 10, 14, and 21 days postinoculation. RESULTS: Administration of E(2), either alone or in combination with P(4), mitigated infection-induced weight loss, hematocrit loss, and hypothermia, compared with females receiving placebo pellets (P < 0.05 in each case). Hormone treatment did not affect levels of parasitemia. Females administered E(2) alone or in combination with P(4) produced 4 to 7 times higher IFN-gamma and IL-10 during peak parasitemia than did females implanted with pellets containing either P(4) alone or placebo (P < 0.05 in each case). Exposure to E(2), either alone or in combination with P(4), increased anti-P chabaudi immunoglobulin G (IgG1) responses and the ratio of IgG1 to IgG2c (P < 0.05 in each case). CONCLUSION: This animal study suggests that physiological levels of estrogen, rather than progesterone, enhance immunity and, possibly, protect females from disease symptoms during malaria infection.

Malaria in Austria 1990-2000.

In Austria, between 1990 and 2000, 924 travel related malaria cases were reported (mean = 84/year). No significant decreasing or increasing trends were observed. P. falciparum (n=517; 55.9%) accounted for the highest number of cases followed by P. vivax or ovale (n=321; 34.7%) and P. malariae (n=29; 2.2%). Most infections were contracted in highly endemic malaria regions (n=686; 74.2%) and most cases were reported from the largest counties: Vienna (n=336, 36.4%), Styria (n=156, 16.8%), and Lower Austria (n=151, 16.3%). Overall, 12 deaths occurred, most were caused by P. falciparum (n=9, 75%; case fatality rate: 1.9%). Data on chemoprophylaxis was available for 752 cases (81.4%) but only half of them (n=367, 48.8%) gave detailed information on the drug used. Data on compliance were obtained for only 45.4% of the cases, with only about 60% of patients completing the full course of prophylaxis.

Atovaquone and proguanil hydrochloride: a review of nonclinical studies.

BACKGROUND: Safe and effective antimalarial drugs are needed for treatment and prophylaxis of malaria. The combination of atovaquone and proguanil hydrochloride is a new antimalarial drug combination that has recently become available in many countries. METHODS: Data were reviewed from nonclinical studies evaluating the microbiology, secondary pharmacology, pharmacokinetics, and toxicology of atovaquone and proguanil hydrochloride. RESULTS: Atovaquone is highly active against asexual erythrocytic stages of Plasmodium falciparum in vitro (IC50 0.7-6 nM) and in animal models. Proguanil per se has only weak antimalarial activity in vitro (IC50 2.4-19 microM), and its effectiveness depends on the active metabolite cycloguanil (IC50 0.5-2.5 nM). The combination of atovaquone and proguanil is synergistic in vitro. Both drugs also have activity against gametocytes and pre-erythrocytic (hepatic) stages of malaria parasites. Atovaquone is a ubiquinone antagonist that inhibits mitochondrial electron transport and collapses mitochondrial membrane potential. The proguanil metabolite cycloguanil is a dihydrofolate reductase inhibitor, but the mode of action of proguanil is unknown. In screening evaluations of secondary pharmacology, neither atovaquone nor proguanil had activity that adversely affected gastrointestinal, cardiovascular, or central or autonomic nervous system functions at clinically relevant concentrations. After oral administration, atovaquone exposure is extensive in rats but limited in dogs, while proguanil and cycloguanil exposure is extensive in dogs but limited in rats. In both species, toxicity was related to proguanil exposure, the principal manifestations being salivation, emesis, and loss of body weight. Neither atovaquone nor proguanil was teratogenic or mutagenic. An increased incidence of hepatic adenomas and adenocarcinomas was seen in mice, but not rats, after lifetime exposure to atovaquone, and appears to be related to species-specific differences in hepatic enzymatic activity. No additional toxicity was evident in animals treated with the combination of atovaquone and proguanil hydrochloride compared to those treated with either drug alone. CONCLUSION: Nonclinical studies of atovaquone and proguanil hydrochloride supported the clinical development of this combination for treatment and prophylaxis of malaria.

[The proper use of antimalarial drugs currently available]. / Du bon usage des médicaments antipaludiques actuellement disponibles.

French medical practitioners have at their disposal several antimalarial drugs for giving chemoprophylaxis to people travelling to a malaria endemic country or treating an imported malaria case in a patient. The choice depends on the contre-indications and indications of each drug, essentially subordinated to the presence and level of Plasmodium falciparum chemosensitivity in the visited area. For prevention, chloroquine alone can be taken in the areas where P. falciparum is absent or not chloroquine resistant; elsewhere, the choice between chloroquine/proguanil or mefloquine depends on knowing the prevalence and level of falciparum chloroquine resistance in these areas. For treatment, the only indications of chloroquine are imported malaria cases either due to P. vivax, P. ovale or P. malariae, or caused by P. falciparum contracted in one of the rare countries where the species is still sensitive to chloroquine. For uncomplicated falciparum malaria cases acquired in a chemoresistance area, mefloquine, halofantrine, sulfadoxine-pyrimethamine or oral quinine is selected, depending on the observed chemoprophylaxis, the contra-indications and the suspicion of chemoresistance type. Whatever the provenance area, P. falciparum in a patient with one or several serious symptoms or possibly profuse vomiting is treated by intravenous quinine, associated with tetracycline if the patient comes from an area known for a low quinine sensitivity of this species. The spectrum of falciparum malaria treatment has recently broadened to include new drugs such as artemisinin, artemether or atovaquone/proguanil, the latter being as yet unauthorized in France.

Tratamento da malária em gestantes / Malaria treatment in pregnancy

Os autores fazem um estudo sobre o tratamento da malária na gestação. Comentam aspectos epidemiológicos e fisiopatológicos da doença e efeitos teratogênicos das drogas.