9 research outputs found
Suppression of polyglutamine toxicity by a Drosophila homolog of myeloid leukemia factor 1
The toxicity of an abnormally long polyglutamine [poly(Q)] tract within specific proteins is the molecular lesion shared by Huntington's disease (HD) and several other hereditary neurodegenerative disorders. By a genetic screen in Drosophila, devised to uncover genes that suppress poly(Q) toxicity, we discovered a Drosophila homolog of human myeloid leukemia factor 1 (MLF1). Expression of the Drosophila homolog (dMLF) ameliorates the toxicity of poly(Q) expressed in the eye and central nervous system. In the retina, whether endogenously or ectopically expressed, dMLF co-localized with aggregates, suggesting that dMLF alone, or through an intermediary molecular partner, may suppress toxicity by sequestering poly(Q) and/or its aggregates
Multiple-stress analysis for isolation of Drosophila longevity genes
Long-lived organisms tend to be more resistant to various forms of environmental stress. An example is the Drosophila longevity mutant, methuselah, which has enhanced resistance to heat, oxidants, and starvation. To identify genes regulated by these three stresses, we made a cDNA library for each by subtraction of "unstressed" from "stressed" cDNA and used DNA hybridization to identify genes that are regulated by all three. This screen indeed identified 13 genes, some already known to be involved in longevity, plus candidate genes. Two of these, hsp26 and hsp27, were chosen to test for their effects on lifespan by generating transgenic lines and by using the upstream activating sequence/GAL4 system. Overexpression of either hsp26 or hsp27 extended the mean lifespan by 30%, and the flies also displayed increased stress resistance. The results demonstrate that multiple-stress screening can be used to identify new longevity genes
Functional analysis of the human androgen receptor using synthetic and naturally occurring mutations
The human androgen receptor (hAR) is a ligand-activated transcription factor, and like other nuclear receptors, consists of a N-terminal modulatory domain, a central DNA-binding domain, and a C-terminal ligand-binding domain (LBD). Several missense mutations in the LBD cause androgen insensitivity syndrome (AI), a condition in XY individuals with absent or subnormal male primary and secondary sexual characteristics. On the other hand, abnormal expansion of a polyglutamine tract in the N-terminal domain of the hAR causes spinal and bulbar muscular atrophy (SBMA) which also affects males and causes milder forms of AI, in addition to adult-onset motor neuron degeneration and gradual wasting and weakening of the muscles of the limbs, face, throat, and tongue. However, it was not clear how and to what extent these mutations contribute to the clinical phenotype of the affected individuals. In order to investigate this matter, I used PCR site-directed mutagenesis to create plasmids expressing hARs with two pairs of missense mutations in the LBD (Val865Leu and Val865Met, and Arg839His and Arg839Cys), discovered in AI individuals with varying severity of the phenotype, and two abnormal expansions of the polyglutamine repeat discovered in SBMA patients (40 and 50 glutamines). I also synthesized plasmids expressing no glutamines (0 glutamines), 12 glutamines, or 20 glutamines in the same N-terminal region of the hAR. These plasmids were transiently expressed in heterologous cells (COS-1 and PC-3), and the mutant hARs were assayed for ligand binding, stability, and transactivational capacity.In contrast to the findings by others (McPhaul et al., 1992; Marcelli et al., 1994), in some instances involving identical mutations, I consistently observed a correlation between the biochemical phenotype of the mutant hARs and the clinical phenotype of AI individuals; that is, the more severe receptor phenotype was associated with the more severe AI. These results support the hypothesis that hAR phenotype is the dominant factor in the development of the secondary sexual characteristics in normal and affected individuals.I also observed a tight negative correlation between polyglutamine tract length and transactivational capacity. This suggests that polyglutamine modulates the activity of the hAR, and that hAR activity might be suppressed in various androgen-sensitive tissues (including motor neurons) in SBMA individuals, thereby contributing to the age of onset and/or progression of the disease, even if it cannot be the primary pathogenic agent of the disease
Genetic Suppression of Polyglutamine Toxicity in Drosophila
A Drosophila model for Huntington's and other polyglutamine diseases was used to screen for genetic factors modifying the degeneration caused by expression of polyglutamine in the eye. Among 7000 P-element insertions, several suppressor strains were isolated, two of which led to the discovery of the suppressor genes described here. The predicted product of one, dHDJ1, is homologous to human heat shock protein 40/HDJ1. That of the second, dTPR2, is homologous to the human tetratricopeptide repeat protein 2. Each of these molecules contains a chaperone-related J domain. Their suppression of polyglutamine toxicity was verified in transgenic flies
Mitochondrial dysfunction in NnaD mutant flies and Purkinje cell degeneration mice reveals a role for Nna proteins in neuronal bioenergetics
The Purkinje cell degeneration (pcd) mouse is a recessive model of neurodegeneration, involving cerebellum and retina. Purkinje cell death in pcd is dramatic, as >99% of Purkinje neurons are lost in 3 weeks. Loss of function of Nna1 causes pcd, and Nna1 is a highly conserved zinc carboxypeptidase. To determine the basis of pcd, we implemented a two-pronge d approach, combining characterization of loss-of-function phenotypes of the Drosophila Nna1 ortholog (NnaD) with proteomics analysis of pcd mice. Reduced NnaD function yielded larval lethality, with survivors displaying phenotypes that mirror disease in pcd. Quantitative proteomics revealed expression alterations for glycolytic and oxidative phosphorylation enzymes. Nna proteins localize to mitochondria, loss of NnaD/Nna1 produces mitochondrial abnormalities, and pcd mice display altered proteolytic processing of Nna1 interacting proteins. Our studies indicate that Nna1 loss of function results in altered bioenergetics and mitochondrial dysfunction
Mitochondrial Dysfunction in NnaD Mutant Flies and Purkinje Cell Degeneration Mice Reveals a Role for Nna Proteins in Neuronal Bioenergetics
SummaryThe Purkinje cell degeneration (pcd) mouse is a recessive model of neurodegeneration, involving cerebellum and retina. Purkinje cell death in pcd is dramatic, as >99% of Purkinje neurons are lost in 3 weeks. Loss of function of Nna1 causes pcd, and Nna1 is a highly conserved zinc carboxypeptidase. To determine the basis of pcd, we implemented a two-pronged approach, combining characterization of loss-of-function phenotypes of the Drosophila Nna1 ortholog (NnaD) with proteomics analysis of pcd mice. Reduced NnaD function yielded larval lethality, with survivors displaying phenotypes that mirror disease in pcd. Quantitative proteomics revealed expression alterations for glycolytic and oxidative phosphorylation enzymes. Nna proteins localize to mitochondria, loss of NnaD/Nna1 produces mitochondrial abnormalities, and pcd mice display altered proteolytic processing of Nna1 interacting proteins. Our studies indicate that Nna1 loss of function results in altered bioenergetics and mitochondrial dysfunction