This observation implies that there exists a network of proteins whose expression levels are altered by ablation of the glucose transporter genes

This observation implies that there exists a network of proteins whose expression levels are altered by ablation of the glucose transporter genes. ribokinase, and hexokinase. Immunoblots employing antisera against these enzymes confirmed that their levels were upregulated, both in glucose transporter null mutants and in wild type parasites starved WAY-100635 Maleate for glucose. Quantitative reverse transcriptase PCR (qRT-PCR) revealed that this levels of mRNAs encoding these enzymes were also enhanced. Global expression profiling using microarrays revealed a limited number of additional changes, although the sensitivity of the microarrays to detect modest changes in amplitude was less than that of two-dimensional gels. Hence, there is likely to be a network of proteins whose expression levels are altered by genetic ablation of glucose transporters, and much of this regulation may be reflected by changes in the levels of the cognate mRNAs. Some of these changes in protein expression may reflect an adaptive response of the parasites to limitation of glucose. are parasitic protozoa that exhibit two principal life cycle stages: promastigotes that live in the gut of the sand travel insect vector and amastigotes that live inside phagolysomal vesicles of vertebrate host macrophages. These two life cycle stages exhibit dramatically different morphologies, promastigotes being spindle shaped, flagellated organisms that are highly motile while amastigotes are oval shaped, non-motile forms that possess only a residual flagellum. These two developmental forms live in very distinct physiological environments. Promastigotes are extracellular, reside at the ambient heat of the sand fly and at a SCDGF-B pH that is close to neutrality [1], and are exposed to varying but often high levels of sugars in the sand travel gut [2]. Amastigotes are intracellular, are exposed to the more elevated heat of the vertebrate and the acidic environment of the phagolysosome [3], and are thought to prevail in a relatively carbohydrate-poor environment [4]. Both life cycle stages are exposed to changes in their milieu, both during propagation and upon the developmental transformation between the two stages. Thus sugars are high in the sand fly gut following a herb nectar meal but drop to much lower levels following digestion of the sugar meal [2]. Similarly, amastigotes may experience changes in the level of carbohydrates available when they are released from the macrophage into the extracellular space following lysis of the host cell, especially in glucose rich serum, and they could be exposed to changes in available metabolites during residency within the macrophage. One fundamental but poorly understood aspect of parasite physiology concerns how these microorganisms adapt to changes in their environments and what molecular mechanisms they employ to mediate these adaptations. Hexose uptake in and related species is usually mediated by 3 hexose or glucose transporters designated GT1, GT2, and GT3 that are encoded by a cluster of linked genes [5]. A null mutant, generated by targeted gene replacement of the gene cluster and designated [5], was deficient in measurable uptake of glucose, fructose, mannose, and galactose [6]. In addition, this glucose transporter null mutant exhibited profound metabolic and cellular changes, including substantially reduced levels of the mannose polymer and storage carbohydrate -mannan [7], decreased cell size and protein content, and increased susceptibility to nutrient starvation, elevated heat, and oxidative stress [6]. These alterations may explain in part why the null mutants did not survive following contamination of murine primary macrophages or WAY-100635 Maleate as culture form amastigotes [5,8]. Since the glucose transporter null mutants exhibit many phenotypic changes, one intriguing question is usually whether these genetically altered parasites also experience alterations in expression of mRNAs or proteins compared to wild type parasites. Such potential changes could represent either mechanisms for adaption to low hexose environments or they could play a role in the observed increased susceptibility to environmental stresses noted above. To determine whether there are changes in mRNA or protein expression WAY-100635 Maleate in glucose transporter null mutants compared to wild type promastigotes, both parasite lines were subjected to protein profiling by two-dimensional gel mRNA and analysis profiling employing an oligonucleotide microarray. Significant changes in the known degrees of specific proteins and mRNAs have already been recognized. 2. Methods and Materials 2.1 Parasite tradition Promastigotes of crazy type (strain MNYZ/BZ/62/M379) or blood sugar transporter null mutant (parasites respectively. The focus of blood sugar in glucose-limited moderate was assessed using the BioVision.