Your search keyword '"Hussein Sanchez-Arroyo"' showing total 4 results

1. Geographic distribution suggests that Solenopsis invicta is the host of predilection for Solenopsis invicta virus 1

Author

Laura Varone, Pat Conant, Robert M. Plowes, Garry A. Webb, David H. Oi, Hussein Sanchez-Arroyo, and Steven M. Valles

Subjects

education.field_of_study, Fire ant, Geography, biology, Ants, Host (biology), Ecology, Population, Allopatric speciation, Insect Viruses, Virus Replication, biology.organism_classification, Geographic distribution, Sympatric speciation, Solenopsis invicta virus-1, Host-Pathogen Interactions, Animals, education, Ecology, Evolution, Behavior and Systematics

Abstract

Solenopsis invicta virus 1 (SINV-1) was found regularly and prevalently in S. invicta. In sampled locations where S. invicta and S. geminata are sympatric (specifically, Gainesville, FL and Travis, TX), SINV-1 was detected in S. geminata. Conversely, in areas in which S. geminata and S. invicta are allopatric, SINV-1 was not detected in S. geminata; these locations included north Australia (n=12), southern Mexico (n=107), Hawaii (n=48), Taiwan (n=12), and the Johnston Atoll (n=6). A similar relationship was observed for S. richteri. In areas in which S. invicta and S. richteri were sympatric, SINV-1 was detected in the S. richteri population, but in areas in which S. invicta and S. richteri were allopatric, SINV-1 was not detected. These occurrences suggest that S. invicta is the host of predilection, or preferred host for SINV-1, and that the congenerics, S. geminata and S. richteri serve as either accidental, reservoir, or transfer hosts. The minus genome strand of SINV-1 was detected in S. geminata and S. richteri indicating that these species may serve as functional hosts capable of supporting SINV-1 replication. SINV-1 was not detected in S. xyloni regardless of its proximity to S. invicta. These results suggest that SINV-1 may be an example of pathogen spillover or pollution.

Published

2013

2. Molecular diversity of the microsporidium Kneallhazia solenopsae reveals an expanded host range among fire ants in North America

Author

David H. Oi, Edward G. LeBrun, DeWayne Shoemaker, Steven M. Valles, Lawrence E. Gilbert, Robert M. Plowes, Hussein Sanchez-Arroyo, Sergio R. Sánchez-Peña, and Marina S. Ascunce

Subjects

Genes, Fungal, Molecular Sequence Data, Zoology, Hymenoptera, RNA, Ribosomal, 16S, Microsporidiosis, Prevalence, Animals, Phylogeny, Ecology, Evolution, Behavior and Systematics, Microsporidia, Unclassified, Genetic diversity, Base Sequence, Phylogenetic tree, biology, Ants, Reverse Transcriptase Polymerase Chain Reaction, Kneallhazia solenopsae, Ecology, Host (biology), biology.organism_classification, Thelohania, Microsporidium, Aculeata, Haplotypes, Microsporidia, North America

Abstract

Kneallhazia solenopsae is a pathogenic microsporidium that infects the fire ants Solenopsis invicta and Solenopsis richteri in South America and the USA. In this study, we analyzed the prevalence and molecular diversity of K. solenopsae in fire ants from North and South America. We report the first empirical evidence of K. solenopsae infections in the tropical fire ant, Solenopsis geminata, and S. geminata × Solenopsis xyloni hybrids, revealing an expanded host range for this microsporidium. We also analyzed the molecular diversity at the 16S ribosomal RNA gene in K. solenopsae from the ant hosts S. invicta, S. richteri, S. geminata and S. geminata × S. xyloni hybrids from North America, Argentina and Brazil. We found 22 16S haplotypes. One of these haplotypes (WD_1) appears to be widely distributed, and is found in S. invicta from the USA and S. geminata from southern Mexico. Phylogenetic analyses of 16S sequences revealed that K. solenopsae haplotypes fall into one of two major clades that are differentiated by 2–3%. In some cases, multiple K. solenopsae haplotypes per colony were found, suggesting either an incomplete homogenization among gene copies within the 16S gene cluster or multiple K. solenopsae variants simultaneously infecting host colonies.

Published

2010

3. Phenology, distribution, and host specificity of Solenopsis invicta virus-1

Author

David H. Oi, Lawrence E. Gilbert, Timothy A. Davis, Juan A. Briano, Luis A. Calcaterra, Yoshifumi Hashimoto, Sanford D. Porter, Hussein Sanchez-Arroyo, Steven M. Valles, Roberto M. Pereira, Karen M. Vail, Robert K. Vander Meer, Jason B. Oliver, Linda M. Hooper-Bùi, Glenn Taniguchi, Rufina Ward, Charles A. Strong, L. C. \\'Fudd\\' Graham, Kenneth Ward, David C. Thompson, and Vedham Karpakakunjaram

Subjects

Picornaviridae Infections, Ants, Reverse Transcriptase Polymerase Chain Reaction, Phenology, Ecology, Molecular Sequence Data, Biological pest control, Zoology, Genome, Viral, Picornaviridae, Hymenoptera, Biology, biology.organism_classification, Host-Parasite Interactions, Geographic distribution, Aculeata, Solenopsis invicta virus-1, Animals, Amino Acid Sequence, PEST analysis, Phylogeny, Ecology, Evolution, Behavior and Systematics, Host specificity

Abstract

Studies were conducted to examine the phenology, geographic distribution, and host specificity of the Solenopsis invicta virus-1 (SINV-1). Two genotypes examined, SINV-1 and -1A, exhibited similar seasonal prevalence patterns. Infection rates among colonies of S. invicta in Gainesville, Florida, were lowest from early winter (December) to early spring (April) increasing rapidly in late spring (May) and remaining high through August before declining again in the fall (September/October). Correlation analysis revealed a significant relationship between mean monthly temperature and SINV-1 (p0.0005, r=0.82) and SINV-1A (p0.0001, r=0.86) infection rates in S. invicta colonies. SINV-1 was widely distributed among S. invicta populations. The virus was detected in S. invicta from Argentina and from all U.S. states examined, with the exception of New Mexico. SINV-1 and -1A were also detected in other Solenopsis species. SINV-1 was detected in Solenopsis richteri and the S. invicta/richteri hybrid collected from northern Alabama and Solenopsis geminata from Florida. SINV-1A was detected in S. geminata and Solenopsis carolinensis in Florida and the S. invicta/richteri hybrid in Alabama. Of the 1989 arthropods collected from 6 pitfall trap experiments from Gainesville and Williston, Florida, none except S. invicta tested positive for SINV-1 or SINV-1A. SINV-1 did not appear to infect or replicate within Sf9 or Dm-2 cells in vitro. The number of SINV-1 genome copies did not significantly increase over the course of the experiment, nor were any cytopathic effects observed. Phylogenetic analyses of SINV-1/-1A nucleotide sequences indicated significant divergence between viruses collected from Argentina and the U.S.

Published

2007

4. Effects of the Synergists Piperonyl Butoxide and S,S,S-Tributyl Phosphorotrithioate on Propoxur Pharmacokinetics in Blattella germanica (Blattodea: Blattellidae)

Author

Hussein Sanchez-Arroyo, Philip G. Koehler, and Steven M. Valles

Subjects

Cockroach, German cockroach, Piperonyl butoxide, Ecology, biology, Cytochrome P450, General Medicine, Monooxygenase, Propoxur, biology.organism_classification, chemistry.chemical_compound, chemistry, Biochemistry, Insect Science, biology.animal, Microsome, biology.protein, Esterase inhibitor

Abstract

Effects of the synergists piperonyl butoxide (PBO) and S,S,S-tributyl phosphorotrithioate (DEF) on propoxur pharmacokinetics were examined in the German cockroach, Blattella germanica (L.). Treatment of adult male German cockroaches with the cytochrome P450 monooxygenase inhibitor, PBO, or the esterase inhibitor, DEF, increased propoxur toxicity by 2- and 6.8-fold, respectively, implicating hydrolysis as a major detoxification route of propoxur in the German cockroach. However, significant hydrolytic metabolism could not be demonstrated conclusively in vitro resulting in a conflict between in situ bioassay data and in vitro metabolic studies. In vitro propoxur metabolism with NADPH-fortified microsomes produced at least nine metabolites. Formation of metabolites was NADPH-dependent; no quantifiable metabolism was detected with cytosolic fractions. However, microsomal fractions lacking an NADPH source did produce a low, but detectable, quantity of metabolites (1.6 pmol). PBO inhibited NADPH-dependent propoxur metabolism in a dose-dependent fashion, implicating cytochrome P450 monooxygenases as the enzyme system responsible for the metabolism. Interestingly, DEF also inhibited the NADPH-dependent metabolism of propoxur, albeit to a lower extent. Treatment with PBO or DEF also caused a significant reduction in the cuticular penetration rate of propoxur. The data demonstrate that unanticipated effects are possible with synergists and that caution must be exercised when interpreting synergist results.

Published

2001