The Hermansky-Pudlak syndrome consists of tyrosine-positive albinism, a defect in the second phase of platelet aggregation, and widespread accumulation of a ceroidlike pigment in tissue. Pulmonary fibrosis has also been reported. In this paper, we describe two families with documented Hermansky-Pudlak syndrome in which four members, two from each family, developed granulomatous colitis. This adds another disease entity to those associated with this syndrome. We discuss possible connecting links between these disease expressions.
The first two steps in the mammalian lysine-degradation pathway are catalyzed by lysine-ketoglutarate reductase and saccharopine dehydrogenase, respectively, resulting in the conversion of lysine to alpha-aminoadipic semialdehyde. Defects in one or both of these activities result in familial hyperlysinemia, an autosomal recessive condition characterized by hyperlysinemia, lysinuria, and variable saccharopinuria. In yeast, lysine-ketoglutarate reductase and saccharopine dehydrogenase are encoded by the LYS1 and LYS9 genes, respectively, and we searched the available sequence databases for their human homologues. We identified a single cDNA that encoded an apparently bifunctional protein, with the N-terminal half similar to that of yeast LYS1 and with the C-terminal half similar to that of yeast LYS9. This bifunctional protein has previously been referred to as "alpha-aminoadipic semialdehyde synthase," and we have tentatively designated this gene "AASS." The AASS cDNA contains an open reading frame of 2,781 bp predicted to encode a 927-amino-acid-long protein. The gene has been sequenced and contains 24 exons scattered over 68 kb and maps to chromosome 7q31.3. Northern blot analysis revealed the presence of several transcripts in all tissues examined, with the highest expression occurring in the liver. We sequenced the genomic DNA from a single patient with hyperlysinemia (JJa). The patient is the product of a consanguineous mating and is homozygous for an out-of-frame 9-bp deletion in exon 15, which results in a premature stop codon at position 534 of the protein. On the basis of these and other results, we propose that AASS catalyzes the first two steps of the major lysine-degradation pathway in human cells and that inactivating mutations in the AASS gene are a cause of hyperlysinemia.
Sodium butyrate and hydroxyurea, effective inhibitors of DNA synthesis in HeLa cells, cause these cells to produce increased levels of the ectopic glycopeptide hormones human chorionic gonadotropin (hCG), follicle stimulating hormone (FSH), and free alpha chains for these hormones. The objective of this study was an assessment of the role of modulation of cell cycle events in the action of these two chemical agents. A variety of experimental approaches was employed to obtain a clear view of the drugs' effects on cells located initially in all phases of the cell cycle. Cells in early G1, G2, or M phase at time of addition of either inhibitor were not arrested at early time points, but by 48 hours became collected at a location characteristic for each drug, near the G1-S phase boundary. Flow microfluorometry (FMF) and thymidine labeling index revealed that butyrate-treated cells arrested late in G1 phase very close to S phase, while hydroxyurea-blocked cells continued to early S phase. Both inhibitors prevented cells originally in S phase from reaching mitosis. S cells exposed to hydroxyurea were killed by 48 hours, but those growing in 5 mM butyrate progressed to the end of S or G2 phase where they became irreversibly arrested although not removed from the monolayer. Analysis of the cell cycle location and viability of each subpopulation resulting from 48 hour exposure to butyrate or hydroxyurea is important for the study of the function of each cellular subset. Treatment of HeLa cells with lower concentrations of butyrate (1 mM) resulted in slowed yet exponential growth. Fraction labeled mitosis (FLM) analysis shows that this is a result of prolongation of the G1 phase.
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