Epidemiologic and Clinical Features of Children and Adolescents Aged <18 Years with Monkeypox - United States, May 17-September 24, 2022.

Data on monkeypox in children and adolescents aged <18 years are limited (1,2). During May 17­September 24, 2022, a total of 25,038 monkeypox cases were reported in the United States,† primarily among adult gay, bisexual, and other men who have sex with men (3). During this period, CDC and U.S. jurisdictional health departments identified Monkeypox virus (MPXV) infections in 83 persons aged <18 years, accounting for 0.3% of reported cases. Among 28 children aged 0­12 years with monkeypox, 64% were boys, and most had direct skin-to-skin contact with an adult with monkeypox who was caring for the child in a household setting. Among 55 adolescents aged 13­17 years, most were male (89%), and male-to-male sexual contact was the most common presumed exposure route (66%). Most children and adolescents with monkeypox were non-Hispanic Black or African American (Black) (47%) or Hispanic or Latino (Hispanic) (35%). Most (89%) were not hospitalized, none received intensive care unit (ICU)­level care, and none died. Monkeypox in children and adolescents remains rare in the United States. Ensuring equitable access to monkeypox vaccination, testing, and treatment is a critical public health priority. Vaccination for adolescents with risk factors and provision of prevention information for persons with monkeypox caring for children might prevent additional infections.

Effects of varying moisture on egg production and longevity of Lutzomyia longipalpis (Diptera: Psychodidae).

The sand fly Lutzomyia longipalpis (Lutz & Neiva) (Diptera: Psychodidae), is the vector of the Neotropical parasite Leishmania chagasi. Designing methods to control the spread of this pathogen involves maintaining large laboratory colonies of these flies. However, transmission studies have been hampered particularly in regard to significant fluctuations in colony productivity. In the process of optimizing our sand fly rearing protocol, we increased moisture levels in the environment of the adult blood-fed female and found that egg development increased, whereas sand fly longevity decreased. Interestingly, continuous moisture from the fourth day after a bloodmeal significantly increased the longevity of the fly, but it did not significantly decrease the number of eggs developed. These results will help guide investigators aiming to manipulate the longevity and productivity of sand fly colonies.

Quinone electrophiles selectively adduct "electrophile binding motifs" within cytochrome c.

Electrophiles generated endogenously, or via the metabolic bioactivation of drugs and other environmental chemicals, are capable of binding to a variety of nucleophilic sites within proteins. Factors that determine site selective susceptibility to electrophile-mediated post-translational modifications, and the consequences of such alterations, remain largely unknown. To identify and characterize chemical-mediated protein adducts, electrophiles with known toxicity were utilized. Hydroquinone, and its mercapturic acid pathway metabolites, cause renal proximal tubular cell necrosis and nephrocarcinogenicity in rats. The adverse effects of HQ and its thioether metabolites are in part a consequence of their oxidation to the corresponding electrophilic 1,4-benzoquinones (BQ). We now report that BQ and 2-(N-acetylcystein-S-yl)benzoquinone (NAC-BQ) preferentially bind to solvent-exposed lysine-rich regions within cytochrome c. Furthermore, we have identified specific glutamic acid residues within cytochrome c as novel sites of NAC-BQ adduction. The microenvironment at the site of adduction governs both the initial specificity and the structure of the final adduct. The solvent accessibility and local pKa of the adducted and neighboring amino acids contribute to the selectivity of adduction. Postadduction chemistry subsequently alters the nature of the final adduct. Using molecular modeling, the impact of BQ and NAC-BQ adduction on cytochrome c was visualized, revealing the spatial rearrangement of critical residues necessary for protein-protein interactions. Consequently, BQ-adducted cytochrome c fails to initiate caspase-3 activation in native lysates and also inhibits Apaf-1 oligomerization into an apoptosome complex in a purely reconstituted system. In summary, a combination of mass spectroscopic, molecular modeling, and biochemical approaches confirms that electrophile-protein adducts produce structural alterations that influence biological function.

Heat shock induces apoptosis independently of any known initiator caspase-activating complex.

Adaptive responses to mild heat shock are among the most widely conserved and studied in nature. More intense heat shock, however, induces apoptosis through mechanisms that remain largely unknown. Herein, we present evidence that heat shock activates an apical protease that stimulates mitochondrial outer membrane permeabilization and processing of the effector caspase-3 in a benzyloxycarbonyl-VAD-fluoromethyl ketone (polycaspase inhibitor)- and Bcl-2-inhibitable manner. Surprisingly, however, neither FADD.caspase-8 nor RAIDD.caspase-2 PIDDosome (p53-induced protein with a death domain) complexes were detected in dying cells, and neither of these initiator caspases nor the endoplasmic reticulum stress-activated caspases-4/12 were required for mitochondrial outer membrane permeabilization. Similarly, although cytochrome c was released from mitochondria following heat shock, functional Apaf-1.caspase-9 apoptosome complexes were not formed, and caspase-9 was not essential for the activation of caspase-3 or the induction of apoptosis. Thus, heat shock does not require any of the known initiator caspases or their activating complexes to promote apoptotic cell death but instead relies upon the activation of an apparently novel apical protease with caspase-like activity.

Negative effect of antibodies against maxadilan on the fitness of the sand fly vector of American visceral leishmaniasis.

Lutzomyia longipalpis expresses a salivary protein called maxadilan (MAX) that functions to dilate vertebrate blood vessels and thereby to facilitate the sand fly's acquisition of blood. We hypothesized that antibodies specific for one of many MAX variants would inhibit vasodilatory function of that variant. In vitro and in vivo experiments showed that antibodies against a specific MAX variant decreased vasodilatory function. More specifically, antibodies against MAX blocked vasodilation of a constricted rabbit aorta. Additionally, a strain of Lu. longipalpis, with a nearly uniform MAX genotype, obtained a larger blood meal from naive BALB/c mice compared with mice that were either immunized with a homologous MAX genotype or sensitized to bites of flies from the same strain. Those flies taking blood from mice sensitized by sand fly bites also laid significantly fewer eggs than when they took blood from naive mice. These results have potential epidemiologic importance in light of the potential use of MAX in a vaccine or as part of a diagnostic test because they imply that a uniform MAX genotype is selected against by the vertebrate host immune response and that antigenic diversity is selected for.

Antigenic diversity in maxadilan, a salivary protein from the sand fly vector of American visceral leishmaniasis.

The salivary protein maxadilan (MAX) is a vasodilator and immunomodulator from the sand fly vector of the protozoan parasite Leishmania chagasi. Vaccinating BALB/c mice with sand fly salivary gland extracts or with MAX protects the host against L. major infection. Because of the potential use of MAX in an anti-Leishmania vaccine, we characterized the vertebrate host IgG response to MAX in the present study. Our immunochemical analysis indicated that antibodies to MAX were detected in BALB/c mice, as well as in pigs and humans, from a area in Nicaragua endemic for Lutzomyia longipalpis. Previous studies demonstrate that the MAX protein is polymorphic on the amino acid level. Our findings suggested that naturally occurring MAX variants were recognized specifically by the host immune system and antigenicity appeared to be associated with amino-acid sequence variability. Thus, antigenic diversity of MAX and possibly of other arthropod salivary proteins may dictate the development of vector-based vaccines(s).