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[
Ciba Found Symp,
1987]
Human lymphatic filariasis is caused mainly by Wuchereria bancrofti, Brugia malayi and Brugia timori. Of the estimated 90.2 million people infected, more than 90% have bancroftian and less than 10% brugian filariasis. The distribution and transmission of the disease are closely associated with socioeconomic and behavioural factors in endemic populations. Urban W. bancrofti infection, as seen in South-East Asia, is related to poor urban sanitation, which leads to intense breeding of Culex quiquefasciatus, the principal vector. Rural strains of W. bancrofti are transmitted primarily by Anopheles spp. and Aedes spp. mosquitoes. Brugian filariasis is mainly a rural disease transmitted by Mansonia, Anopheles and Aedes spp. mosquitoes. The periodic form of B. malayi is principally a human parasite, whereas the subperiodic form is zoonotically transmitted in some countries. The control of filariasis has relied on chemotherapy, vector control and reduction of human-vector contact. Although eradication of W. bancrofti and periodic B. malayi can be achieved, it is possible only to reduce transmission of zoonotic subperiodic B. malayi in some areas. A rational approach to control should consider ecological, socioeconomic and behavioural factors and, where feasible, integrate control programmes into the delivery system for primary health care.
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[
Seminars in Developmental Biology,
1992]
At the 4-cell stage of the C. elegans embryo, three axes can be defined: anterior-posterior (A-P), dorsal-ventral (D-V), and left-right (L-R). The A-P axis first becomes obvious in the newly fertilized 1-cell embryo. Pronouned cytoplasmic assymmetries arise along the A-P axis during the first cell cycle, after which the zygote undergoes a series of stem cell-like cleavages with an A-P orientation of the mitotic spindle; these cleavages generate several somatic founder cells and a primordial germ cell. The D-V and L-R axes are defined by the direction of spindle rotation as the 2-cell embryo divides into four cells. In contrast to the A-P axis, there do not appear to be cellular asymmetries associated with the D-V and L-R axes, and both axes can easily be reversed by micromanipulation. Thus, with respect to the roles that the embryonic axes serve in cell-fate determination in the early C. elegans embryo, it appears that internally transmitted developmental information is differentially segregated along the A-P axis, but not along the D-V or L-R axes. Instead, D-V and L-R differences in the fates of cells within lineages appear to be dictated by differential
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[
Cell Microbiol,
2018]
Legionella pneumophila is a ubiquitous environmental bacterium that has evolved to infect and proliferate within amoebae and other protists. It is thought that accidental inhalation of contaminated water particles by humans is what has enabled this pathogen to proliferate within alveolar macrophages and cause pneumonia. However, the highly evolved macrophages are equipped more sophisticated innate defense mechanisms than protists, such as the evolution of phagotrophic feeding into phagocytosis with more evolved innate defense processes. Not surprisingly, the majority of proteins involved in phagosome biogenesis (~80%) have origins in the phagotrophy stage of evolution. There are a plethora of highly evolved cellular and innate metazoan processes, not represented in Protist biology, that are modulated by L. pneumophila; including TLR2 signaling, NF-B, apoptotic and inflammatory processes, histone modification, caspases, and the NLRC-Naip5 inflammasomes. Importantly, L. pneumophila infects hemocytes of the invertebrate Galleria mellonella, kill G. mellonella larvae, and proliferate in and kill Drosophila adult flies and Caenorhabditis elegans. Although co-evolution with protist hosts has provided a substantial blueprint for L. pneumophila to infect macrophages, we discuss the further evolutionary aspects of co-evolution of L. pneumophila and its adaptation to modulate various highly evolved innate metazoan processes prior to becoming a human pathogen.
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[
Neurotoxicology,
2008]
Manganese (Mn) is a transition metal that is essential for normal cell growth and development, but is toxic at high concentrations. While Mn deficiency is uncommon in humans, Mn toxicity is known to be readily prevalent due to occupational overexposure in miners, smelters and possibly welders. Excessive exposure to Mn can cause Parkinson''s disease-like syndrome; patients typically exhibit extrapyramidal symptoms that include tremor, rigidity and hypokinesia [Calne DB, Chu NS, Huang CC, Lu CS, Olanow W. Manganism and idiopathic parkinsonism: similarities and differences. Neurology 1994;44(9):1583-6; Dobson AW, Erikson KM, Aschner M. Manganese neurotoxicity. Ann NY Acad Sci 2004;1012:115-28]. Mn-induced motor neuron diseases have been the subjects of numerous studies; however, this review is not intended to discuss its neurotoxic potential or its role in the etiology of motor neuron disorders. Rather, it will focus on Mn uptake and transport via the orthologues of the divalent metal transporter (DMT1) and its possible implications to Mn toxicity in various categories of eukaryotic systems, such as in vitro cell lines, in vivo rodents, the fruitfly, Drosophila melanogaster, the honeybee, Apis mellifera L., the nematode, Caenorhabditis elegans and the baker''s yeast, Saccharomyces cerevisiae.
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[
Int J Biochem Cell Biol,
2013]
Dicarbonyl/L-xylulose reductase (DCXR) is a highly conserved and phylogenetically widespread enzyme converting L-xylulose into xylitol. It also reduces highly reactive -dicarbonyl compounds, thus performing a dual role in carbohydrate metabolism and detoxification. Enzymatic properties of DCXR from yeast, fungi and mammalian tissue extracts are extensively studied. Deficiency of the DCXR gene causes a human clinical condition called pentosuria and low DCXR activity is implicated in age-related diseases including cancers, diabetes, and human male infertility. While mice provide a model to study clinical condition of these diseases, it is necessary to adopt a physiologically tractable model in which genetic manipulations can be readily achieved to allow the fast genetic analysis of an enzyme with multiple biological roles. Caenorhabditis elegans has been successfully utilized as a model to study DCXR. Here, we discuss the biochemical properties and significance of DCXR activity in various human diseases, and the utility of C. elegans as a research platform to investigate the molecular and cellular mechanism of the DCXR biology.
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[
East Afr Med J,
1997]
Apoptosis differs from necrosis in that no inflammatory changes occur. The understanding of apoptosis was greatly improved by the discovery of a natural model of apoptosis in Caenorhabditis elegans, a nematode worm. The study of this worm led to the discovery of two sets of genes, the prosuicide genes and the antisuicide genes which control apoptosis. Apoptosis is an active process that involves w activation of specific enzymes. The understanding of the molecular biology of apoptosis may in future lead to the availability of a potent weapon to use against cancer and to modify cell death that occurs in the neurodegenerative disorders.AD - Department of Morbid Anatomy and Forensic Medicine, Faculty of Basic Medical Sciences, College of Health Sciences, Obafemi Awolowo University, Ile-Ife, Nigeria.FAU - Olasode, B JAU - Olasode BJLA - engPT - Journal ArticlePT - ReviewPT - Review, TutorialCY - KENYATA - East Afr Med JJID - 0372766SB - IM
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[
Mutat Res,
2009]
Fanconi anemia (FA) is a severe recessive disorder with a wide range of clinical manifestations [M. Levitus, H. Joenje, J.P. de Winter, The Fanconi anemia pathway of genomic maintenance, Cell Oncol. 28 (2006) 3-29]. In humans, 13 complementation groups have been identified to underlie FA: A, B, C, D1, D2, E, F, G, I, J, L, M, and N [W. Wang, Emergence of a DNA-damage response network consisting of Fanconi anaemia and BRCA proteins, Nat. Rev. Genet. 8 (2007) 735-748]. Cells defective for any of these genes display chromosomal aberrations and sensitivity to DNA interstrand cross-links (ICLs). It has therefore been suggested that the 13 FA proteins constitute a pathway for the repair of ICLs, and that a deficiency in this repair process causes genomic instability leading to the different clinical phenotypes. However, the exact nature of this repair pathway, or even whether all 13 FA proteins are involved at some stage of a linear repair process, remains to be defined. Undoubtedly, the recent identification and characterisation of FA homologues in model organisms, such as Caenorhabditis elegans, will help facilitate an understanding of the function of the FA proteins by providing new analytical tools. To date, sequence homologues of five FA genes have been identified in C. elegans. Three of these homologues have been confirmed:
brc-2 (FANCD1/BRCA2),
fcd-2 (FANCD2), and
dog-1 (FANCJ/BRIP1); and two remain to be characterised: W02D3.10 (FANCI) and
drh-3 (FANCM). Here we review how the nematode can be used to study FA-associated DNA repair, focusing on what is known about the ICL repair genes in C. elegans and which important questions remain for the field.
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[
Parasitol Res,
2015]
Parasites including helminthes, protozoa, and medical arthropod vectors are a major cause of global infectious diseases, affecting one-sixth of the world's population, which are responsible for enormous levels of morbidity and mortality important and remain impediments to economic development especially in tropical countries. Prevalent drug resistance, lack of highly effective and practical vaccines, as well as specific and sensitive diagnostic markers are proving to be challenging problems in parasitic disease control in most parts of the world. The impressive progress recently made in genome-wide analysis of parasites of medical importance, including trematodes of Clonorchis sinensis, Opisthorchis viverrini, Schistosoma haematobium, S. japonicum, and S. mansoni; nematodes of Brugia malayi, Loa loa, Necator americanus, Trichinella spiralis, and Trichuris suis; cestodes of Echinococcus granulosus, E. multilocularis, and Taenia solium; protozoa of Babesia bovis, B. microti, Cryptosporidium hominis, Eimeria falciformis, E. histolytica, Giardia intestinalis, Leishmania braziliensis, L. donovani, L. major, Plasmodium falciparum, P. vivax, Trichomonas vaginalis, Trypanosoma brucei and T. cruzi; and medical arthropod vectors of Aedes aegypti, Anopheles darlingi, A. sinensis, and Culex quinquefasciatus, have been systematically covered in this review for a comprehensive understanding of the genetic information contained in nuclear, mitochondrial, kinetoplast, plastid, or endosymbiotic bacterial genomes of parasites, further valuable insight into parasite-host interactions and development of promising novel drug and vaccine candidates and preferable diagnostic tools, thereby underpinning the prevention and control of parasitic diseases.
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[
Clin Microbiol Infect,
2011]
Lymphatic filariasis (LF) and onchocerciasis are parasitic nematode infections that are responsible for a major disease burden in the African continent. Disease symptoms are induced by the immune reactions of the host, with lymphoedema and hydrocoele in LF, and dermatitis and ocular inflammation in onchocerciasis. Wuchereria bancrofti and Onchocerca volvulus, the species causing LF and onchocerciasis in Africa, live in mutual symbiosis with Wolbachia endobacteria, which cause a major part of the inflammation leading to symptoms and are antibiotic targets for treatment. The standard microfilaricidal drugs ivermectin and albendazole are used in mass drug administration programmes, with the aim of interrupting transmission, with a consequent reduction in the burden of infection and, in some situations, leading to regional elimination of LF and onchocerciasis. Co-endemicity of Loa loa with W. bancrofti or O. volvulus is an impediment to mass drug administration with ivermectin and albendazole, owing to the risk of encephalopathy being encountered upon administration of ivermectin. Research into new treatment options is exploring several improved delivery strategies for the classic drugs or new antibiotic treatment regimens for anti-wolbachial chemotherapy.
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[
Endocr Metab Immune Disord Drug Targets,
2012]
Filarial infections are characterized by immunopathological phenomena, that are responsible for the onset of often dramatic pathological outcomes, such as blindness (Onchocerca volvulus) and elephantiasis (W. bancrofti). In addition, the long-term survival (as long as 10 years) of these parasites in otherwise immunocompetent hosts indicates that these nematodes are capable of manipulating the host immune response. The ground-breaking discovery of the bacterial endosymbiont Wolbachia, which resides in most filarial nematodes causing disease, has led to increasing interest in the role it may play in immuno-modulation, pro-inflammatory pathology and other aspects of filarial infection. Indeed, Wolbachia has been shown to be responsible for exacerbating inflammation (as in river blindness), while at the same time blocking efficient elimination of parasites through the host immune response (Onchocerca ochengi). While studies aimed at identifying Wolbachia as a potential target for anti-filarial therapy are at the forefront of current research, understanding its role in the immunology of filarial infection is a fascinating field that has yet to uncover many secrets.