Renee Kapteijn scite author profile

Horizontal gene transfer in bacteria is widely believed to occur via conjugation, transduction and transformation. These mechanisms facilitate the passage of DNA across the protective cell wall using sophisticated machinery. Here, we report that cell wall-deficient bacteria can engulf DNA and other extracellular material via an endocytosis-like process. Specifically, we show that L-forms of the filamentous actinomycete Kitasatospora viridifaciens can take up plasmid DNA, polysaccharides (dextran) and 150-nm lipid nanoparticles. The process involves invagination of the cytoplasmic membrane, leading to formation of intracellular vesicles that encapsulate extracellular material. DNA uptake is not affected by deletion of genes homologous to comEC and comEA, which are required for natural transformation in other species. However, uptake is inhibited by sodium azide or incubation at 4 °C, suggesting the process is energy-dependent. The encapsulated materials are released into the cytoplasm upon degradation of the vesicle membrane. Given that cell wall-deficient bacteria are considered a model for early life forms, our work reveals a possible mechanism for primordial cells to acquire food or genetic material before invention of the bacterial cell wall.

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DNA uptake by cell wall-deficient bacteria reveals a putative ancient macromolecule uptake mechanism

Kapteijn

Shitut

Ashmann

et al. 2022

Preprint

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Horizontal gene transfer in bacteria is widely believed to occur via three main mechanisms: conjugation, transduction and transformation. These mechanisms facilitate the passage of DNA across the protective cell wall using sophisticated machinery. We present here a new mechanism of DNA uptake that is independent of canonical DNA uptake machineries and is used by bacteria that live without a cell wall. We show that the cell wall-deficient bacteria engulf extracellular material, whereby intracellular vesicles are formed, and DNA is internalized. This mechanism is not specific to DNA, and allows uptake of other macromolecules and even 125 nm lipid nanoparticles (LNPs). Uptake was prevented by molecules known to inhibit eukaryotic endocytosis, suggesting this to be an energy-dependent process. Given that cell wall-deficient bacteria are considered a model for early life forms, our work provides a possible mechanism for primordial cells to acquire new genetic material or food before invention of the bacterial cell wall.

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Two-dimensional membrane protein patterns of acute myeloid leukemia cells and mature myeloid cells after various ectolabeling procedures

Jong

Dekker

Kapteijn

et al. 1984

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Surface exposed membrane proteins of malignant cells may offer important clues about the differentiation stage of the cell or may contain proteins specific for the malignant state. We have studied the surface exposed membrane proteins of human acute myeloid leukemia cells employing the lactoperoxidase, periodate, or the neuraminidase/galactose oxidase ectolabeling procedures. One- dimensional membrane protein patterns were prepared from 20 patients, and from 19 patients, two-dimensional patterns were prepared according to OFarrell. No consistent differences in membrane proteins could be found between patients classified as M1, M2, M4, or M5 (FAB classification). A diagram of membrane proteins from acute myeloid leukemia cells subjected to two-dimensional electrophoresis could be composed from the results obtained. About 25 different membrane proteins can be indicated. Two-dimensional patterns, after the various ectolabeling procedures, were also prepared from mature myeloid cells, visualizing about 18 different membrane proteins. Comparison of these and the undifferentiated myeloid leukemia cell pattern reveals some maturation-linked or leukemia-associated differences. The most relevant proteins will be discussed, along with their association with a recently described “malignancy marker” with a molecular weight of 68,000 daltons.

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Two-dimensional membrane protein patterns of myeloid cells, at various stages of differentiation

Jong¹,

Dekker²,

Kapteijn³

et al. 1986

Leukemia Research

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DNA uptake by cell wall-deficient bacteria reveals a putative ancient macromolecule uptake mechanism

Kapteijn

Shitut

Aschmann

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

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Renee Kapteijn

Endocytosis-like DNA uptake by cell wall-deficient bacteria

DNA uptake by cell wall-deficient bacteria reveals a putative ancient macromolecule uptake mechanism

Two-dimensional membrane protein patterns of acute myeloid leukemia cells and mature myeloid cells after various ectolabeling procedures

Two-dimensional membrane protein patterns of myeloid cells, at various stages of differentiation

DNA uptake by cell wall-deficient bacteria reveals a putative ancient macromolecule uptake mechanism

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