Helix Academy 01 The New Kid
Dimitri Rajawi
Photograph: Helix Academy president Preston Castille reviews plans and architectural drawings for an Artificial Intelligence and Medical Academy that is due to open in the Opelousas area in 2025. (Photograph by Bobby Ardoin.)
Architectural plans for a $34 million artificial intelligence and medical academy set to open outside Opelousas in 2025, were unveiled to St. Landry Parish school board members during a meeting on Thursday night.
Helix Academy president Preston Castille announced that school officials have purchased about 16 acres next to Our Saviors Church in order to construct the academy that will be used for teaching elementary students in grades kindergarten through fifth grade.
Helix officials last year received approval from school officials to build at least one academy near Opelousas, after voters parish wide refused to pass a referendum that would have doubled the property tax millage now used for salaries and maintenance for public school employees.
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The functions of the helix E (W97-F105), an amphiphilic lumenal 310 helix of the major antenna of photosystem II (LHCII), are still unidentified. To elucidate the roles of individual amino acid residue of the helix E, alanine scanning mutagenesis has been performed to mutate every residue of this domain to alanine. The influence of every alanine substitution on the structure and function of LHCII has been investigated biochemically and spectroscopically. The results show that all mutations have little impact on the pigment binding and configuration. However, many mutants presented decreased thermo- or photo-stability compared with the wild type, highlighting the significance of this helix to the stability of LHCII. The most critical residue for stability is W97. The mutant W97A yielded very fragile trimeric pigment protein complexes. The structural analysis revealed that the hydrogen bonding and aromatic interactions between W97, F195, F194 and a water molecule contributed greatly to the stability of LHCII. Moreover, Q103A and F105A have been identified to be able to reinforce the tendency of aggregation in vitro. The structural analysis suggested that the enhancement in aggregation formation for Q103A and F105A might be attributed to the changing hydrophobicity of the region.
N2 - The minichromosome maintenance (MCM) proteins are essential conserved proteins required for DNA replication in archaea and eukaryotes. MCM proteins are believed to provide the replicative helicase activity that unwinds template DNA ahead of the replication fork. Consistent with this hypothesis, MCM proteins can form hexameric complexes that possess ATP-dependent DNA unwinding activity. The molecular mechanism by which the energy of ATP hydrolysis is harnessed to DNA unwinding is unknown, although the ATPase activity has been attributed to a highly conserved AAA+ family ATPase domain. Here we show that changes to N- and C-terminal motifs in the single MCM protein from the archaeon Methanothermobacter thermautotrophicus (MthMCM) can modulate ATP hydrolysis, DNA binding, and duplex unwinding. Furthermore, these motifs appear to influence the movement of the -a- insert in helix-2 of the MCM ATPase domain. Removal of this motif from MthMCM increased dsDNA-stimulated ATP hydrolysis and increased the affinity of the mutant complex for ssDNA and dsDNA. Deletion of the helix-2 insert additionally resulted in the abrogation of DNA unwinding. Our results provide significant insight into the molecular mechanisms used by the MCM helicase to both regulate and execute DNA unwinding.
AB - The minichromosome maintenance (MCM) proteins are essential conserved proteins required for DNA replication in archaea and eukaryotes. MCM proteins are believed to provide the replicative helicase activity that unwinds template DNA ahead of the replication fork. Consistent with this hypothesis, MCM proteins can form hexameric complexes that possess ATP-dependent DNA unwinding activity. The molecular mechanism by which the energy of ATP hydrolysis is harnessed to DNA unwinding is unknown, although the ATPase activity has been attributed to a highly conserved AAA+ family ATPase domain. Here we show that changes to N- and C-terminal motifs in the single MCM protein from the archaeon Methanothermobacter thermautotrophicus (MthMCM) can modulate ATP hydrolysis, DNA binding, and duplex unwinding. Furthermore, these motifs appear to influence the movement of the -a- insert in helix-2 of the MCM ATPase domain. Removal of this motif from MthMCM increased dsDNA-stimulated ATP hydrolysis and increased the affinity of the mutant complex for ssDNA and dsDNA. Deletion of the helix-2 insert additionally resulted in the abrogation of DNA unwinding. Our results provide significant insight into the molecular mechanisms used by the MCM helicase to both regulate and execute DNA unwinding.
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