Searches / Cell. Physiol. Biochem. [JOURNAL]

Cell. Physiol. Biochem. [JOURNAL]

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Erratum.

Cell Physiol Biochem · 2023 Oct · PMID 37905774 · Publisher ↗

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Emerging Roles of SPT5 in Transcription.

Pandey V, Punniyamoorthy S, Pokharel YR

Cell Physiol Biochem · 2023 Oct · PMID 37876219 · Publisher ↗

Suppressor of Ty homolog-5 (SPT5) discovered in the yeast mutant screens as a suppressor of mutation caused by the insertion of the Transposons of yeast (Ty) element along with SPT4, with which it forms a holoenzyme comp... Suppressor of Ty homolog-5 (SPT5) discovered in the yeast mutant screens as a suppressor of mutation caused by the insertion of the Transposons of yeast (Ty) element along with SPT4, with which it forms a holoenzyme complex known as DRB sensitivity-inducing factor (DSIF) and plays an essential role in the regulation of transcription. SPT5 is a highly conserved protein across all three domains of life and performs critical functions in transcription, starting from promoter-proximal pausing to termination. We also highlight the emerging role of SPT5 in other non-canonical functions, such as the regulation of post-translational modifications (PTM) and the transcriptional regulation of non-coding genes. Also, in brief, we highlight the clinical implications of SPT5 dysregulation.

Immunogenicity and Protection by DnaK and SpaA Recombinant Proteins Against in a Murine Model.

Godoy NL, de Moraes JB, de Castro CA … +5 more , Santana JPP, Zangirolami TC, da Silva AJ, Novo-Mansur MTM, Anibal FF

Cell Physiol Biochem · 2023 Oct · PMID 37815427 · Publisher ↗

BACKGROUND/AIMS: Swine erysipelas is a disease caused by , a Gram-positive bacillus, which has great economic importance because it leads to the loss of the swine herd. To control this disease, animals are immunized with... BACKGROUND/AIMS: Swine erysipelas is a disease caused by , a Gram-positive bacillus, which has great economic importance because it leads to the loss of the swine herd. To control this disease, animals are immunized with a cellular vaccine of killed or attenuated , but even with herd vaccination, cases of swine erysipelas outbreaks have been reported in the United States, China and Japan, leading to the search for other antigenic components of the bacteria that may promote greater protection against . The surface protein SpaA from has been shown to be a candidate to constitute a subunit vaccine, since it has already been reported to induce a host immune response against the bacterium. DnaK, a hsp70 molecular chaperone, also seems to be a good candidate in the composition of a vaccine, as it has been demonstrated to be an antigenic protein of the bacteria. METHODS: This work evaluated the immunogenicity and protection induced by the e SpaA and DnaK recombinant proteins in a murine model, by intramuscular administration to mice with two doses of 100 µg at 21-day interval between them. The candidate proteins were tested either separately and together, compared with the commercial vaccine and the non-vaccination condition, and mice were challenged with a virulent strain of . Serum was collected to assess the produced antibodies and peripheral blood cells, whereas spleen and kidney tissues were assayed for presence by colony counting. RESULTS: A survival curve of the animals was performed, which confirmed the protection induced by the proteins. IgG antibodies increased in the animal serum inoculated with the proteins when compared to the control, and a significant delay in disease symptoms was observed. CONCLUSION: These results suggest that DnaK and SpaA are immunogenic in mice and interfere with the disease development.

Induced Pluripotent Stem Cells (Ipscs) Based Liver Organoid: the Benefits and Challenges.

Septiana WL, Noviantari A, Antarianto RD

Cell Physiol Biochem · 2023 Sep · PMID 37767740 · Publisher ↗

The liver is the main metabolic organ and functions to regulate many physiological functions in the human body. Approximately 70% of liver mass consists of hepatic cells (hepatocytes), which execute the liver's metabolic... The liver is the main metabolic organ and functions to regulate many physiological functions in the human body. Approximately 70% of liver mass consists of hepatic cells (hepatocytes), which execute the liver's metabolic processes. When liver damage progresses to a chronic condition, such as end-stage liver disease (ESLD) or cirrhosis of the liver, the patient's only option for therapy is organ transplantation if the supply of available transplanted organs is insufficient to meet the patient's needs. The fundamental objective of the search for alternatives to organ transplantation has been to make liver tissue replacement more accessible and to produce hepatic and bioartificial liver tissue. Multiple hepatic cell lineages can be formed from human-induced pluripotent stem cells (hiPSCs) from embryoid bodies to become mature hepatocytes. hiPSCs also show a promising source for manufacturing human liver spheroids and are made to produce three-dimensional hepatobiliary organoids, and in some ways, it also briefly highlights important features of early hepatogenesis. Unquestionably, the art of cell culture has evolved to include the use of organoid technology as a resource for learning human biology in the context of health and illness. Organoids are essentially miniature organs that can grow in a three-dimensional matrix to resemble genuine organs in terms of both structure and function. This review summarized alternative protocols to differentiate hepatocytes from iPSC and to produce liver organoids based on iPSC in various ways. The growth of human iPSCs into liver organoids has been accomplished using several procedures.

Activity of Lysosomal ABCC3, ABCC5 and ABCC10 is Responsible for Lysosomal Sequestration of Doxorubicin and Paclitaxel-Oregongreen488 in Paclitaxel-Resistant Cancer Cell Lines.

Gronkowska K, Michlewska S, Robaszkiewicz A

Cell Physiol Biochem · 2023 Sep · PMID 37767694 · Publisher ↗

BACKGROUND/AIMS: Cancer cell multidrug resistance induced by paclitaxel contributes to the high failure rates of chemotherapy and relapse of the disease. Several mechanisms have been described that underlie the observed... BACKGROUND/AIMS: Cancer cell multidrug resistance induced by paclitaxel contributes to the high failure rates of chemotherapy and relapse of the disease. Several mechanisms have been described that underlie the observed resistance, including the overexpression of ABCB1 (P-glycoprotein), which represents an ATP-binding cassette (ABC) transmembrane protein, and its functional occurrence in lysosomal membranes is linked to drug accumulation in these organelles. METHODS: Using clinically-relevant models of paclitaxel-resistant triple-negative breast cancer and non-small cell lung cancer cell lines, we provide evidence for the role of ABCC subfamily members in the lysosomal sequestration of drugs in multidrug resistant phenotypes. Proteins expression level and its cellular localisation was measured using Western Blot and confocal microscopy. Drug accumulation was analysed by confocal microscopy and flow cytometry. Drug cytotoxicity was tested using resasurin assay and anexin V propidium iodide staining. RESULTS: Regardless of the alteration in gene expression, paclitaxel induced the intracellular redistribution of ABCC3, ABCC5 and ABCC10 and their enrichment in lysosomes. The use of ABCC inhibitors and transient silencing of these three genes limited the accumulation of doxorubicin and paclitaxel-OregonGreen488 in lysosomes, while having little impact on the total drug level inside cells. The cancer cells were also sensitized to various structurally unrelated chemotherapeutics of differing acidity. CONCLUSION: The results suggest that lysosome membranes anchored ABCC proteins which remained functionally active and were capable to load chemotherapeutics into lysosomes in paclitaxel-resistant cancer cells. Therefore, targeting of lysosomal ABCC transporters may help to overcome paclitaxel-induced resistance by reducing the accumulation of drugs in lysosomes.

Tyrosine-Mutant AAV8 Vector Mediated Efficient and Safe Gene Transfer of Pigment Epithelium-Derived Factor to Mouse Lungs.

Ferreira DP, Martini SV, Oliveira HA … +11 more , Silva AL, Shenoy S, Chen D, Simon V, Han E, West NE, Suk JS, Rocco PRM, Petrs-Silva H, Morales MM, Cruz FF

Cell Physiol Biochem · 2023 Sep · PMID 37724045 · Full text

BACKGROUND/AIMS: Recombinant adeno-associated viruses (rAAV) are an important tool for lung targeted gene therapy. Substitution of tyrosine with phenylalanine residues (Y-F) in the capsid have been shown to protect the A... BACKGROUND/AIMS: Recombinant adeno-associated viruses (rAAV) are an important tool for lung targeted gene therapy. Substitution of tyrosine with phenylalanine residues (Y-F) in the capsid have been shown to protect the AAV vector from ubiquitin/proteasome degradation, increasing transduction efficiency. We tested the mutant Y733F-AAV8 vector for mucus diffusion, as well as the safety and efficacy of pigment epithelium-derived factor (PEDF) gene transfer to the lung. METHODS: For this purpose, Y733F-AAV8-PEDF (10 viral genome) was administered intratracheally to C57BL/6 mice. Lung mechanics, morphometry, and inflammation were evaluated 7, 14, 21, and 28 days after injection. RESULTS: The tyrosine-mutant AAV8 vector was efficient at penetrating mucus in ex vivo assays and at transferring the gene to lung cells after in vivo instillation. Increased levels of transgene mRNA were observed 28 days after vector administration. Overexpression of PEDF did not affect in vivo lung parameters. CONCLUSION: These findings provide a basis for further development of Y733F-AAV8-based gene therapies for safe and effective delivery of PEDF, which has anti-angiogenic, anti-inflammatory and anti-fibrotic activities and might be a promising therapy for lung inflammatory disorders.

Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697994 · Publisher ↗

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Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697993 · Publisher ↗

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Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697992 · Publisher ↗

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Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697991 · Publisher ↗

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Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697990 · Publisher ↗

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Retraction Statement.

Cell Physiol Biochem · 2023 Aug · PMID 37697989 · Publisher ↗

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Erratum.

Cell Physiol Biochem · 2023 Aug · PMID 37697988 · Publisher ↗

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Erratum.

Cell Physiol Biochem · 2023 Aug · PMID 37697987 · Publisher ↗

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Cell Physiol Biochem · 2023 Aug · PMID 37697986 · Publisher ↗

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Cell Physiol Biochem · 2023 Aug · PMID 37697985 · Publisher ↗

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Cell Physiol Biochem · 2023 Aug · PMID 37697984 · Publisher ↗

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Erratum.

Cell Physiol Biochem · 2023 Aug · PMID 37697983 · Publisher ↗

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Cell Physiol Biochem · 2023 Aug · PMID 37697982 · Publisher ↗

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Erratum.

Cell Physiol Biochem · 2023 Aug · PMID 37697981 · Publisher ↗

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