Nobuo KITADA (北田 昇雄)

ABSTRACT

In vivo imaging of bacterial infection models enables noninvasive and temporal analysis of individuals, enhancing our understanding of infectious disease pathogenesis. Conventional in vivo imaging methods for bacterial infection models involve the insertion of the bacterial luciferase LuxCDABE into the bacterial genome, followed by imaging using an expensive ultrasensitive charge-coupled device (CCD) camera. However, issues such as limited light penetration into the body and lack of versatility have been encountered. We focused on near-infrared (NIR) light, which penetrates the body effectively, and attempted to establish an in vivo imaging method to evaluate the number of lung-colonizing bacteria during the course of bacterial pneumonia. This was achieved by employing a novel versatile system that combines plasmid-expressing firefly luciferase bacteria, NIR substrate, and an inexpensive, scientific complementary metal-oxide semiconductor (sCMOS) camera. The D-luciferin derivative “TokeOni,” capable of emitting NIR bioluminescence, was utilized in a mouse lung infection model of Acinetobacter baumannii , an opportunistic pathogen that causes pneumonia and is a concern due to drug resistance. TokeOni exhibited the highest sensitivity in detecting bacteria colonizing the mouse lungs compared with other detection systems such as LuxCDABE, enabling the monitoring of changes in bacterial numbers over time and the assessment of antimicrobial agent efficacy. Additionally, it was effective in detecting A. baumannii clinical isolates and Klebsiella pneumoniae . The results of this study are expected to be used in the analysis of animal models of infectious diseases for assessing the efficacy of therapeutic agents and understanding disease pathogenesis.

IMPORTANCE

Conventional animal models of infectious diseases have traditionally relied upon average assessments involving numerous individuals, meaning they do not directly reflect changes in the pathology of an individual. Moreover, in recent years, ethical concerns have resulted in the demand to reduce the number of animals used in such models. Although in vivo imaging offers an effective approach for longitudinally evaluating the pathogenesis of infectious diseases in individual animals, a standardized method has not yet been established. To our knowledge, this study is the first to develop a highly versatile in vivo pulmonary bacterial quantification system utilizing near-infrared luminescence, plasmid-mediated expression of firefly luciferase in bacteria, and a scientific complementary metal-oxide semiconductor camera. Our research holds promise as a useful tool for assessing the efficacy of therapeutic drugs and pathogenesis of infectious diseases.

Abstract

Pathogenic protein aggregates, called amyloids, are etiologically relevant to various diseases, including neurodegenerative Alzheimer disease. Catalytic photooxygenation of amyloids, such as amyloid‐β (Aβ), reduces their toxicity; however, the requirement for light irradiation may limit its utility in large animals, including humans, due to the low tissue permeability of light. Here, we report that Cypridina luciferin analogs, dmCLA‐Cl and dmCLA‐Br, promoted selective oxygenation of amyloids through chemiexcitation without external light irradiation. Further structural optimization of dmCLA‐Cl led to the identification of a derivative with a polar carboxylate functional group and low cellular toxicity: dmCLA‐Cl‐acid. dmCLA‐Cl‐acid promoted oxygenation of Aβ amyloid and reduced its cellular toxicity without photoirradiation. The chemiexcited oxygenation developed in this study may be an effective approach to neutralizing the toxicity of amyloids, which can accumulate deep inside the body, and treating amyloidosis.

Abstract

T‐cell acute lymphoblastic leukemia (T‐ALL) is one of the most frequently occurring cancers in children and is associated with a poor prognosis. Here, we performed large‐scale screening of natural compound libraries to identify potential drugs against T‐ALL. We identified three low‐molecular‐weight compounds (auxarconjugatin‐B, rumbrin, and lavendamycin) that inhibited the proliferation of the T‐ALL cell line CCRF‐CEM, but not that of the B lymphoma cell line Raji in a low concentration range. Among them, auxarconjugatin‐B and rumbrin commonly contained a polyenyl 3‐chloropyrrol in their chemical structure, therefore we chose auxarconjugatin‐B for further analyses. Auxarconjugatin‐B suppressed the in vitro growth of five human T‐ALL cell lines and two T‐ALL patient‐derived cells, but not that of adult T‐cell leukemia patient‐derived cells. Cultured normal T cells were several‐fold resistant to auxarconjugatin‐B. Auxarconjugatin‐B and its synthetic analogue Ra#37 depolarized the mitochondrial membrane potential of CCRF‐CEM cells within 3 h of treatment. These compounds are promising seeds for developing novel anti‐T‐ALL drugs.

Abstract

Tumors contain various stromal cells, such as immune cells, endothelial cells, and fibroblasts, which contribute to the development of a tumor‐specific microenvironment characterized by hypoxia and inflammation, and are associated with malignant progression. In this study, we investigated the activity of intratumoral hypoxia‐inducible factor (HIF), which functions as a master regulator of the cellular response to hypoxia and inflammation. We constructed the HIF activity‐monitoring reporter gene hypoxia‐response element‐Venus‐Akaluc (HVA) that expresses the green fluorescent protein Venus and modified firefly luciferase Akaluc in a HIF activity‐dependent manner, and created transgenic mice harboring HVA transgene (HVA‐Tg). In HVA‐Tg, HIF‐active cells can be visualized using AkaBLI, an ultra‐sensitive in vivo bioluminescence imaging technology that produces an intense near‐infrared light upon reaction of Akaluc with the D‐luciferin analog AkaLumine‐HCl. By orthotopic transplantation of E0771, a mouse triple negative breast cancer cell line without a reporter gene, into HVA‐Tg, we succeeded in noninvasively monitoring bioluminescence signals from HIF‐active stromal cells as early as 8 days after transplantation. The HIF‐active stromal cells initially clustered locally and then spread throughout the tumors with growth. Immunohistochemistry and flow cytometry analyses revealed that CD11b⁺F4/80⁺ macrophages were the predominant HIF‐active stromal cells in E0771 tumors. These results indicate that HVA‐Tg is a useful tool for spatiotemporal analysis of HIF‐active tumor stromal cells, facilitating investigation of the roles of HIF‐active tumor stromal cells in tumor growth and malignant progression.