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J Bioenerg Biomembr,
1993]
The ADP/ATP, phosphate, and oxoglutarate/malate carrier proteins found in the inner membranes of mitochondria, and the uncoupling protein from mitochondria in mammalian brown adipose tissue, belong to the same protein superfamily. Established members of this superfamily have polypeptide chains approximately 300 amino acids long that consist of three tandem related sequences of about 100 amino acids. The tandem repeats from the different proteins are interrelated, and probably have similar secondary structures. The common features of this superfamily are also present in nine proteins of unknown functions characterized by DNA sequencing in various species, most notably in Caenorhabditis elegans and Saccharomyces cerevisiae. The high level expression in Escherichia coli of the bovine oxoglutarate/malate carrier, and the reconstitution of active carrier from the expressed protein, offers encouragement that the identity of superfamily members of known sequence but unknown function may be uncovered by a similar route.
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Genetics,
2024]
Extracellular vesicles (EVs) encompass a diverse array of membrane-bound organelles released outside cells in response to developmental and physiological cell needs. EVs play important roles in remodeling the shape and content of differentiating cells and can rescue damaged cells from toxic or dysfunctional content. EVs can send signals and transfer metabolites between tissues and organisms to regulate development, respond to stress or tissue damage, or alter mating behaviors. While many EV functions have been uncovered by characterizing ex vivo EVs isolated from body fluids and cultured cells, research using the nematode Caenorhabditis elegans has provided insights into the in vivo functions, biogenesis, and uptake pathways. The C. elegans EV field has also developed methods to analyze endogenous EVs within the organismal context of development and adult physiology in free-living, behaving animals. In this review, we summarize major themes that have emerged for C. elegans EVs and their relevance to human health and disease. We also highlight the diversity of biogenesis mechanisms, locations, and functions of worm EVs and discuss open questions and unexplored topics tenable in C. elegans, given the nematode model is ideal for light and electron microscopy, genetic screens, genome engineering, and high-throughput omics.
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Traffic,
2003]
Proteins must be correctly folded and assembled to fulfill their functions as assigned by genetic code. All living cells have developed systems to counteract protein unfolding or misfolding. A typical example of such a homeostatic response is triggered when unfolded proteins are accumulated in the endoplasmic reticulum. Eukaryotic cells cope with endoplasmic reticulum stress by attenuating translation, generally to decrease the burden on the folding machinery, as well as by inducing transcription of endoplasmic reticulum-localized molecular chaperones and folding enzymes to augment folding capacity. These translational and transcriptional controls are collectively termed the unfolded protein response. The unfolded protein response is unique in that the molecular mechanisms it uses to transmit signals from the endoplasmic reticulum lumen to the nucleus are completely different from those used for signaling from the plasma membrane. Frame switch splicing (a term newly proposed here) and regulated intramembrane proteolysis (proposed by Brown et al., Cell 2000; 100: 391-398) employed by the unfolded protein response represent novel ways to activate a signaling molecule post-transcriptionally and post-translationally, respectively. They are critically involved in various cellular regulation pathways ranging from bacterial extracytoplasmic stress response to differentiation of mature B cells into antibody-secreting plasma cells. Further, mammalian cells take advantage of differential properties between the two mechanisms to determine the fate of proteins unfolded or misfolded in the endoplasmic reticulum. This review focuses on the transcriptional control that occurs during the unfolded protein response in various species.
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J Fungi (Basel),
2020]
<i>Malassezia</i> is a lipid-dependent genus of yeasts known for being an important part of the skin mycobiota. These yeasts have been associated with the development of skin disorders and cataloged as a causal agent of systemic infections under specific conditions, making them opportunistic pathogens. Little is known about the host-microbe interactions of <i>Malassezia</i> spp., and unraveling this implies the implementation of infection models. In this mini review, we present different models that have been implemented in fungal infections studies with greater attention to <i>Malassezia</i> spp. infections. These models range from in vitro (cell cultures and ex vivo tissue), to in vivo (murine models, rabbits, guinea pigs, insects, nematodes, and amoebas). We additionally highlight the alternative models that reduce the use of mammals as model organisms, which have been gaining importance in the study of fungal host-microbe interactions. This is due to the fact that these systems have been shown to have reliable results, which correlate with those obtained from mammalian models. Examples of alternative models are <i>Caenorhabditis elegans</i>, <i>Drosophila melanogaster</i>, <i>Tenebrio molitor</i>, and <i>Galleria mellonella</i>. These are invertebrates that have been implemented in the study of <i>Malassezia</i> spp. infections in order to identify differences in virulence between <i>Malassezia</i> species.