Ryoko Tsukamoto scite author profile

During plant reproduction, sperm cells are delivered to ovules through growing pollen tubes. This process involves tip-localized receptor kinases regulating integrity and/or guidance of pollen tubes, whose localizations must be strictly regulated. However, the molecular basis for tip-localization of these molecules remains largely elusive. Here we show that a pair of AP180 N-terminal homology domain-containing proteins, PICALM5a and PICALM5b, is responsible for the tip-localization of ANXUR receptor kinases acting in an autocrine signaling pathway required for pollen tube integrity in Arabidopsis thaliana. The picalm5a picalm5b double mutant exhibits reduced fertility, and the double mutant pollen is defective in pollen tube integrity with premature bursts. The tip localization of ANXUR proteins is severely impaired in picalm5a picalm5b pollen tubes, whereas another receptor kinase PRK6 acting in pollen tube guidance is not affected. Based on these results, we propose that PICALM5 proteins serve as specific loading adaptors to recycle ANXUR proteins.

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Geometry-Based Self-Assembly of Histone–DNA Nanostructures at Single-Nucleotide Resolution

Serag

Aikeremu

Tsukamoto

et al. 2019

ACS Nano

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Histones are basic protein monomers capable of interacting with DNA, providing the mechanism of DNA compaction inside the cell nucleus. The well-ordered assembly process of histone and DNA is a potential candidate as the approach for building DNA-protein nanostructures. Here, utilizing the sequence-independent histone-DNA interaction, we present an approach to selfassemble histones and single-stranded DNA (ssDNA) to form well-defined histone-DNA (sHD) nanoparticles and their multidimensional cross-linked complexes (cHD). By using various molecular biology and microscopy techniques, we elucidate the structure of these complexes, and we show that they are formed at carefully controlled conditions of temperature, ionic-strength, concentration and incubation time. We also demonstrate using a set of ssDNA molecular rulers and a geometric accommodation model that the assembly of sHD and cHD particles proceed with precise geometry so that the number of ssDNA in these particles can be programmed by the length of ssDNA. We further show that the formation of cHD amplifies the effect of the length of ssDNA on the self-assembly, allowing for distinguishing ssDNA of different lengths at single nucleotide resolution. We envision that our geometry-directed approach of self-assembling histone-DNA nanostructures and the fundamental insights can serve as a structural platform to advance building precisely-ordered DNA-protein nanostructures.

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Chemical synthesis of Torenia plant pollen tube attractant proteins by KAHA ligation

et al. 2022

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Ryoko Tsukamoto

ANTH domain-containing proteins are required for the pollen tube plasma membrane integrity via recycling ANXUR kinases

Geometry-Based Self-Assembly of Histone–DNA Nanostructures at Single-Nucleotide Resolution

Chemical synthesis of Torenia plant pollen tube attractant proteins by KAHA ligation

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