We have isolated and characterised the nuclear gene that codes for the 30.4-kDa subunit of the peripheral arm of complex I from Neurospora crassa. The single-copy gene was localised on chromosome VI of the fungal genome by restriction fragment length polymorphism mapping. An extra copy of the gene was introduced into a strain of N. crassa by transformation. This strain was crossed with another strain in order to inactivate, by repeat-induced point mutations, both copies of the duplication carried by the parental transformant. Ascospore progeny from the cross were analysed and a mutant strain lacking the 30.4-kDa protein, nuo30.4, was isolated and further characterised. The mutant appears to assemble the membrane arm of complex I, while formation of the peripheral arm is prevented. Nevertheless, the mutant grows reasonably well--indicating that this well conserved protein is not essential for vegetative growth--and is able to mate with other strains both as male or female. Strains with multiple mutations are readily obtained from heterozygous crosses between different complex I mutants of N. crassa. On the other hand, homozygous crosses between several mutants, including nuo30.4, fail to produce ascospores. These results suggest that complex I plays an essential role during the sexual phase of the life cycle of the fungus.
The nuclear gene coding for the 20.8-kDa subunit of the membrane arm of respiratory chain NADH: ubiquinone reductase (Complex I) from Neurospora crassa, nuo-20.8, was localized on linkage group I of the fungal genome. A genomic DNA fragment containing this gene was cloned and a duplication was created in a strain of N. crassa by transformation. To generate RIP (repeat-induced point) mutations in the duplicated sequence, the transformant was crossed with another strain carrying an auxotrophic marker on chromosome I. To increase the chance of finding an isolate with a non-functional nuo-20.8 gene, random progeny from the cross were selected against this auxotrophy since RIP of the target gene will only occur in the nucleus carrying the duplication. Among these, we isolated and characterised a mutant strain that lacks the 20.8 kDa mitochondrial protein, indicating that this cysteine-rich polypeptide is not essential. Nevertheless, the absence of the 20.8-kDa subunit prevents the full assembly of complex I. It appears that the peripheral arm and two intermediates of the membrane arm of the enzyme are still formed in the mutant mitochondria. The NADH: ubiquinone reductase activity of sonicated mitochondria from the mutant is rotenone insensitive. Electron microscopy of mutant mitochondria does not reveal any alteration in the structure or numbers of the organelles.
Alpha-thalassemias are among the most common genetic diseases in the world. They
are characterized by hypochromic and microcytic anemia and great clinical
variability, ranging from a practically asymptomatic phenotype to severe anemia,
which can lead to intrauterine or early neonatal death. Deletions affecting the
α-globin genes, located on chromosome 16p13.3, are the main causes of
α-thalassemia. Multiplex ligation-dependent probe amplification (MLPA) can be
used to detect rearrangements that cause α-thalassemia, particularly large
deletions involving the whole α cluster and/or deletions in the HS-40 region.
Here, MLPA was used to investigate the molecular basis of α-thalassemia in five
unrelated patients, three of whom had Hb H disease. In addition to the
-α3.7 deletion identified in the patients with Hb H disease, four
different α0 deletions removing 15 to 225 kb DNA segments were found:
two of them remove both the α genes, one affects only the regulatory element
(HS-40) region, and another one extends over the entire α cluster and the HS-40
region. These results illustrate the diversity of α-thalassemia deletions in the
Brazilian population and highlight the importance of molecular investigation in
cases that present with microcytosis and hypochromia without iron deficiency and
normal or reduced Hb A2 levels..
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