Mutations in the spin gene are characterized by an extraordinarily strong rejection behavior of female flies in response to male courtship. They are also accompanied by decreases in the viability, adult life span, and oviposition rate of the flies. In spin mutants, some oocytes and adult neural cells undergo degeneration, which is preceded by reductions in programmed cell death of nurse cells in ovaries and of neurons in the pupal nervous system, respectively. The central nervous system (CNS) of spin mutant flies accumulates autofluorescent lipopigments with characteristics similar to those of lipofuscin. The spin locus generates at least five different transcripts, with only two of these being able to rescue the spin behavioral phenotype; each encodes a protein with multiple membrane-spanning domains that are expressed in both the surface glial cells in the CNS and the follicle cells in the ovaries. Orthologs of the spin gene have also been identified in a number of species from nematodes to humans. Analysis of the spin mutant will give us new insights into neurodegenerative diseases and aging.
Glycogen synthase kinase 3 (GSK3) plays important roles in Wnt and insulin signaling, cell fate determination, and Alzheimer-like tau phosphorylation. We discovered an isoform of tau protein kinase I (TPKI) / GSK3b with a 13 amino acid insert in the catalytic domain owing to alternative splicing. The alternative transcripts were found in the brains of the mouse, rat and human, with highly conserved sequences. The variant protein, named TPKI2 / GSK3b2, was abundant in the brain. Immunohistochemistry indicated differential distribution of the conventional and the new TPKI / GSK3b isoforms within young neurons. TPKI2 / GSK3b2 showed decreased kinase activities towards two phosphorylation sites on tau compared with the conventional isoform. Immunohistochemistry indicated that TPKI2 / GSK3b2 occurs predominantly in the neuronal soma, while TPKI1 / GSK3b1 is found both in the soma and processes. These results indicate that the new splice isoform has a different function. Because the amino acid insert occurs in the domain implicated in interaction with a protein phosphatase in a homologous kinase cdk-2, the alternative splicing can regulate multiprotein complex formation and function involving TPKI / GSK3b. Keywords: glycogen synthase kinase 3, protein kinase subdomain, splice variant, tau phosphorylation, tau protein kinase.
Most strains of Pseudomonas aeruginosa produce various types of bacteriocins (pyocins), namely, R-, F-, and S-type pyocins. The production of all types of pyocins was shown to be regulated by positive (prtN) and negative (prtR) regulatory genes. The prtN gene activates the expression of various pyocin genes, probably by the interaction of its product with the DNA sequences conserved in the 5' noncoding regions of the pyocin genes. The prtR gene represses the expression of the prtN gene, and its product, predicted from the nucleotide sequence, has a structure characteristic of phage repressors and seems to be inactivated by the RecA protein activated by DNA damage. A model for the regulation of the pyocin genes is proposed.
Pyocins S1 and S2 are S-type bacteriocins of Pseudomonas aeruginosa with different receptor recognition specificities. The genetic determinants of these pyocins have been cloned from the chromosomes of P. aeruginosa NIH-H and PAO, respectively. Each determinant constitutes an operon encoding two proteins of molecular weights 65,600 and 10,000 (pyocin S1) or 74,000 and 10,000 (pyocin S2) with a characteristic sequence (P box), a possible regulatory element involved in the induction of pyocin production, in the 5' upstream region. These pyocins have almost identical primary sequences; only the amino-terminal portions of the large proteins are substantially different. The sequence homology suggests that pyocins S1 and S2, like pyocin AP41, originated from a common ancestor of the E2 group colicins. Purified pyocins S1 and S2 make up a complex of the two proteins. Both pyocins cause breakdown of chromosomal DNA as well as complete inhibition of lipid synthesis in sensitive cells. The large protein, but not the pyocin complex, shows in vitro DNase activity. This activity is inhibited by the small protein of either pyocin. Putative domain structures of these pyocins and their killing mechanism are discussed.
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