Trehalose, a disaccharide present in many non-mammalian species, protects cells against various environmental stresses. Whereas some of the protective effects may be explained by its chemical chaperone properties, its actions are largely unknown. Here we report a novel function of trehalose as an mTOR-independent autophagy activator. Trehalose-induced autophagy enhanced the clearance of autophagy substrates like mutant huntingtin and the A30P and A53T mutants of ␣-synuclein, associated with Huntington disease (HD) and Parkinson disease (PD), respectively. Furthermore, trehalose and mTOR inhibition by rapamycin together exerted an additive effect on the clearance of these aggregate-prone proteins because of increased autophagic activity. By inducing autophagy, we showed that trehalose also protects cells against subsequent pro-apoptotic insults via the mitochondrial pathway. The dual protective properties of trehalose (as an inducer of autophagy and chemical chaperone) and the combinatorial strategy with rapamycin may be relevant to the treatment of HD and related diseases, where the mutant proteins are autophagy substrates.Trehalose is a non-reducing disaccharide found in many organisms, including bacteria, yeast, fungi, insects, invertebrates, and plants. It is the natural hemolymph sugar of invertebrates. It functions to protect the integrity of cells against various environmental stresses like heat, cold, desiccation, dehydration, and oxidation by preventing protein denaturation (1). Many of the stress-protecting properties of trehalose were discovered in yeast (2); however, it also has beneficial effects in mammals where it is not endogenously synthesized. For instance, it may be a valuable tool for cryopreservation of cells (1, 3). It is not clear how trehalose mediates many of its protective effects, but some may be via its ability to act as chemical chaperone and influence protein folding through direct protein-trehalose interactions (4). Trehalose inhibits amyloid formation of insulin in vitro (5) and prevents aggregation of -amyloid associated with Alzheimer disease (6). Recently, trehalose was shown to inhibit polyglutamine (polyQ) 3 -mediated protein aggregation in vitro, reduce mutant huntingtin aggregates and toxicity in cell models and alleviate polyQ-induced pathology in the R6/2 mouse model of Huntington disease (HD) (7). This protective effect was suggested to be caused by trehalose binding to expanded polyQ and stabilizing the partially unfolded mutant protein.HD is an autosomal-dominant neurodegenerative disorder caused by a CAG trinucleotide repeat expansion, which results in an abnormally long polyQ tract in the N terminus of the huntingtin protein. Asymptomatic individuals have 35 or fewer CAG repeats, whereas HD is caused by 36 or more repeats. HD and related polyQ expansion diseases are associated with the formation of intraneuronal inclusions (also known as aggregates) by the mutant proteins containing the expanded polyQ tracts. The toxicity of mutant huntingtin is thought to be exposed...
Research into late embryogenesis abundant (LEA) proteins has been ongoing for more than 20 years but, although there is a strong association of LEA proteins with abiotic stress tolerance particularly dehydration and cold stress, for most of that time, their function has been entirely obscure. After their initial discovery in plant seeds, three major groups (numbered 1, 2 and 3) of LEA proteins have been described in a range of different plants and plant tissues. Homologues of groups 1 and 3 proteins have also been found in bacteria and in certain invertebrates. In this review, we present some new data, survey the biochemistry, biophysics and bioinformatics of the LEA proteins and highlight several possible functions. These include roles as antioxidants and as membrane and protein stabilisers during water stress, either by direct interaction or by acting as molecular shields. Along with other hydrophilic proteins and compatible solutes, LEA proteins might also serve as "space fillers" to prevent cellular collapse at low water activities. This multifunctional capacity of the LEA proteins is probably attributable in part to their structural plasticity, as they are largely lacking in secondary structure in the fully hydrated state, but can become more folded during water stress and/or through association with membrane surfaces. The challenge now facing researchers investigating these enigmatic proteins is to make sense of the various in vitro defined functions in the living cell: Are the LEA proteins truly multi-talented, or are they still just misunderstood?
LEA (late embryogenesis abundant) proteins in both plants and animals are associated with tolerance to water stress resulting from desiccation and cold shock. However, although various functions of LEA proteins have been proposed, their precise role has not been defined. Recent bioinformatics studies suggest that LEA proteins might behave as molecular chaperones, and the current study was undertaken to test this hypothesis. Recombinant forms of AavLEA1, a group 3 LEA protein from the anhydrobiotic nematode Aphelenchus avenae, and Em, a group 1 LEA protein from wheat, have been subjected to functional analysis. Heat-stress experiments with citrate synthase, which is susceptible to aggregation at high temperatures, suggest that LEA proteins do not behave as classical molecular chaperones, but they do exhibit a protective, synergistic effect in the presence of the so-called chemical chaperone, trehalose. In contrast, both LEA proteins can independently protect citrate synthase from aggregation due to desiccation and freezing, in keeping with a role in water-stress tolerance; similar results were obtained with lactate dehydrogenase. This is the first evidence of anti-aggregation activity of LEA proteins due to water stress. Again, a synergistic effect of LEA and trehalose was observed, which is significant given that non-reducing disaccharides are known to accumulate during dehydration in plants and nematodes. A model is proposed whereby LEA proteins might act as a novel form of molecular chaperone, or 'molecular shield', to help prevent the formation of damaging protein aggregates during water stress.
The ETS gene Fli-1 is involved in the induction of erythroleukemia in mice by Friend murine leukemia virus and Ewings sarcoma in children. Mice with a targeted null mutation in the Fli-1 locus die at day 11.5 of embryogenesis with loss of vascular integrity leading to bleeding within the vascular plexus of the cerebral meninges and specific downregulation of Tek/Tie-2, the receptor for angiopoietin-1. We also show that dysmegakaryopoiesis in Fli-1 null embryos resembles that frequently seen in patients with terminal deletions of 11q (Jacobsen or Paris-Trousseau Syndrome). We map the megakaryocytic defects in 14 Jacobsen patients to a minimal region on 11q that includes the Fli-1 gene and suggest that dysmegakaryopoiesis in these patients may be caused by hemizygous loss of Fli-1.
A novel polymerase chain reaction (PCR) technique has been combined with chromosome flow sorting to characterise two lymphoblastoid cell lines and one medullary thyroid carcinoma cell line carrying translocations close to the locus for multiple endocrine neoplasia type 2A (MEN 2A). Five hundred copies of the derivative chromosome(s) were flow sorted from each cell line and amplified by degenerate oligonucleotide-primed-polymerase chain reaction (DOP-PCR). This generated pools of DNA sequences corresponding to the abnormal chromosomes, which were then used as probes in fluorescence in situ hybridisation (FISH) experiments on normal metaphase cells. The resultant chromosome paints revealed the portions of the normal chromosomes related to those involved in the translocations. By this technique, translocation breakpoints in bands p15, q11.2, and q21 of chromosome 10 were defined in the above cell lines, in two cases refining previous cytogenetic data. This study shows that flow sorting of aberrant chromosomes and chromosome painting can be used as a rapid aid to cytogenetic analysis, particularly in cases of difficult karyotypes, such as tumours. Furthermore, the DOP-PCR technique described here will have applications to other areas of genome analysis, such as cloning of new markers; its design will allow a general and representative amplification to occur from any starting DNA in any species.
The susceptibility loci for the three multiple endocrine neoplasia (MEN) type 2 syndromes have been mapped to the region of chromosome 10q11.2 containing the RET proto-oncogene, which codes for a receptor tyrosine kinase. The majority of MEN 2A and familial medullary thyroid carcinoma results from missense mutations within one of five cysteine codons in the extracellular domain of the RET proto-oncogene. We now report a missense mutation, resulting in the substitution of a threonine for a methionine at codon 918 in the tyrosine kinase catalytic domain, in the germline of 26 of 28 apparently distinct families with MEN 2B. DNA from five of 13 apparently sporadic MTC and one of 12 apparently sporadic phaeochromocytomas harboured a similar mutation, but the corresponding germline DNA was wildtype in each case.
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